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Acid Mine Drainage Jerry Bigham Wendy Gagliano The Ohio State University, Columbus, Ohio, U.S.A.
INTRODUCTION
MINE DRAINAGE CHEMISTRY
What Is Acid Mine Drainage?
Mine drainage is a complex biogeochemical process involving oxidation-reduction, hydrolysis, precipitation, and dissolution reactions as well as microbial catalysis.[1] The entire sequence is commonly represented by Reaction (1), which describes the overall oxidation of pyrite by oxygen in the presence of water to form iron hydroxide [Fe(OH)3] and sulfuric acid.
Acid mine drainage refers to metal-rich sulfuric acid solutions released from mine tunnels, open pits, and waste rock piles (Table 1). Similar solutions are produced by the drainage of some coastal wetlands, resulting in the formation of acid sulfate soils. Acid mine drainage typically ranges in pH from 2 to 4; however, extreme sites like Iron Mountain, California have produced pH values as low as 3.6.[1] Neutral to alkaline mine drainage is also common in areas where the surrounding geologic units contain carbonate rocks to buffer acidity (Table 1). Why Is Acid Mine Drainage a Problem? Soils and spoils exposed to acid mine drainage do not support vegetation and are susceptible to erosion. When acid mine drainage enters natural waterways, changes in pH and the formation of voluminous precipitates of metal hydroxides can devastate fish populations and other aquatic life (Fig. 1). The corrosion of engineered structures like bridges is also greatly accelerated. There may be as many as 500,000 inactive or abandoned mines in the United States, with mine drainage severely impacting approximately 19,300 km of streams and more than 72,000 ha of lakes and reservoirs.[2,3] Once initiated, mine drainage may persist for decades, making it a challenging problem to solve.
3 1 FeS2ðsÞ þ 3 O2ðgÞ þ 3 H2 Oð1Þ 4 2 ! FeðOHÞ3ðsÞ þ 2H2 SO4ðaqÞ
The actual oxidation process is considerably more complicated. Pyrite and related sulfide minerals contain both Fe and S in reduced oxidation states. When exposed to oxygen and water the sulfur moiety is oxidized first, releasing Fe2þ and sulfuric acid to solution [Reaction (2)]. The rate of oxidation is dependent on environmental factors like temperature, pH, Eh, and relative humidity as well as mineral surface area and microbial catalysis. 1 FeS2ðsÞ þ 3 O2ðgÞ þ H2 Oð1Þ ! FeðaqÞ 2þ 2 þ 2SO4ðaqÞ 2 þ 2HðaqÞ þ
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001582 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
ð2Þ
Reaction (2) is most important in the initial stages of mine drainage generation and can be either strictly abiotic or mediated by contact with sulfur-oxidizing bacteria.[4] The Fe2þ released by pyrite decomposition is rapidly oxidized by oxygen at pH >3 as per Reaction (3).
What Causes Acid Mine Drainage? Mine drainage results from the oxidation of sulfide minerals such as pyrite (cubic FeS2), marcasite (orthorhombic FeS2), pyrrhotite (Fe1XS), chalcopyrite (CuFeS2) and arsenopyrite (FeAsS). These minerals are commonly found in coal and ore deposits and are stable until exposed to oxygen and water. Their oxidation causes the release of metals and the production of sulfuric acid. This process can occur as a form of natural mineral weathering but is exacerbated by mining because of the sudden, large-scale exposure of unweathered rock to atmospheric conditions.
ð1Þ
FeðaqÞ 2þ þ
1 1 O2ðgÞ þ HðaqÞ þ ! FeðaqÞ 3þ þ H2 OðIÞ 4 2 ð3Þ
If acidity generated by Reaction (2) exceeds the buffering capacity of the system, the pH eventually decreases. Below pH 3, Fe3þ solubility increases and a second mechanism of pyrite oxidation becomes important[5] [Reaction (4)]. FeS2ðsÞ þ 14FeðaqÞ 3þ þ 8H2 OðIÞ ! 15FeðaqÞ 2þ þ 2SO4ðaqÞ 2 þ 16HðaqÞ þ
ð4Þ 1
2
Acid Mine Drainage
Table 1 Summary of mine drainage from 101 bituminous coal mine sites in Pennsylvania Range pH
Median
Mean
2.7–7.3
5.2
3.6
Fe (mg=L)
0.16–512.0
43.0
58.9
Al (mg=L)
0.01–108.0
1.3
9.8
Mn (mg=L)
0.12–74.0
2.2
6.2
SO4 (mg=L)
120–2000
580.0
711.2
From Cravotta, C., III. USGS: Lemoyne, PA, 2001.
In this case, pyrite is oxidized by Fe3þ resulting in the generation of even greater acidity than when oxygen is the primary oxidant. Pyrite decomposition is thus controlled by the rate at which Fe2þ is converted to Fe3þ at low pH.[6] At pH 6.5) environments. Schwertmannite is commonly found in drainage waters with pH ranging from 2.8 to 4.5 and with
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Fig. 1 Mixing of acid mine drainage (at right) with a natural stream resulting in the formation of voluminous precipitates of iron minerals.
moderate to high sulfate contents. It may be the dominant phase controlling major and minor element activities in most acid mine drainage. Jarosite forms in more extreme environments with pH 100% 15-bar water content. Vitrisols with 20% C) have bulk density of about 0.2 g cm3. Soils with low C% (vitric horizons) have low clay content and often relatively high bulk density (>0.8 g cm3), but the soils have, in general, low bulk density characteristic of Andisols (predominately 2% Alo þ (1=2)Feo. The presence of vitric materials (various types of tephra) is also recognized by lowering this limit to as low as 0.4%, depending on the abundance of vitric materials. Most of the Icelandic Vitrisols meet the >0.4% Alo þ (1=2)Feo criterion for Andisols, but this limit seems arbitrary in Iceland and it can be doubted that it does provide meaningful separation of soils with abundance of vitric materials. On a world basis, vitric soils are poorly accounted for and recognized as weakly developed soils or parent material (tephra), with [Alo þ (1=2)Feo] < 0.4%. The uniqueness of these parent materials is recognized in some other classification systems such as for New Zealand with ‘‘Pumice Soils.’’[9]
ANDIC SOILS AND CRYOTURBATION Cryoturbation occurs with great intensity in Iceland.[1,10] The evidence is seen by cryoturbation in the soils and as various surface features such as ‘‘thufur’’ (hummocks) and a variety of active solifluction features. Cryoturbation in Iceland is enhanced by several factors. Water is pumped from shallow water table in wetlands. Freezethaw cycles are numerous and the soil temperature stays near 0 C for extensive periods which enhances stationary freezing front. The physical properties of Andosols are
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important as well. Both saturated and unsaturated hydraulic conductivity of the soils are rapid which enhances water transfer to the freezing front. The great water holding capacity (often >40% at 15-bar suction in freely drained soils) also contributes water that freezes in the soil. An additional factor is the thixotropic nature of many soils, as this allows easy deformation of the soil by the ice formation.
SOIL EROSION The climate of Iceland is cold and subjected to periodic cold spells that exert stress on Icelandic ecosystems, as do ashfall events during volcanic eruptions. The vegetation of Iceland evolved in the absence of grazing animals. These factors render Icelandic ecosystems particularly sensitive to disturbance and reduced resilience caused by grazing and other land use. Soil erosion in Iceland has remained intense for the past 1200 years since the settlement by Vikings. A unique feature of soil erosion in Iceland is that the full depth of the soil mantle that has formed in eolian and tephra sediments is truncated, leaving barren surfaces (deserts) behind. A survey of erosion in Iceland has recently been published[11] showing the great extent and severity of soil erosion in Iceland. The Icelandic soils are extremely vulnerable to erosion, both by wind and water for many reasons. The formation of stable silt size clusters enhances saltation movement of soil particles making the soils susceptible to wind erosion. The lack of cohesion while wet and the thixotropic nature of the soils intensify water erosion and landslides. These andic properties that have reduced resistance against erosion are important contributing factors to the severe soil erosion in Iceland.
CONCLUSIONS A classification scheme specific to Iceland has been developed, and it has been used to produce a new 1:500,000 soil map.[1] Icelandic soils are primarily Andosols and Vitrisols according to the Icelandic scheme, which are both classified as Andisols according to Soil Taxonomy. The Icelandic soil environment is characterized by cold humid climate and a steady flux of vitric materials to the surface which, together
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Andisols in Iceland
with drainage, are major factors dominating soil formation in Iceland. The extensive Icelandic desert environments are unique considering the humid climate of Iceland. The soils of the deserts are characterized by basaltic vitric materials and are termed Vitrisols. The andic soil characteristics of the Andisols, such as high water holding capacity, rapid hydraulic conductivity, thixotropy, and stable silt-sized aggregates, have important implications for intensive cryoturbation and soil erosion in Iceland.
REFERENCES 1. Arnalds, O. Volcanic soils of Iceland. In Volcanic Soil Resources. Occurrence, Development, and Properties; Arnalds, O., Stahr, K., Eds.; Catena Special Issue, Elsevier: Amsterdam, in press. 2. Quantin, P. Volcanic soils of France. In Volcanic Soil Resources. Occurrence, Development, and Properties; Arnalds, O., Stahr, K., Eds.; Catena Special Issue, Elsevier: Amsterdam, in press. 3. Arnalds, O. Sandy deserts of Iceland. J. Arid Environ. 2001, 47 (3), 359–371. 4. FAO. World Reference Base for Soil Resources. World Soil Resources Reports; FAO: Rome, 1998; Vol. 84. 5. Soil Survey Staff. Keys to Soil Taxonomy, 8th Ed.; USDA-NRCS: Washington, DC, 1998. 6. Parfitt, R.L.; Kimble, J.M. Conditions for formation of allophane in soils. Soil Sci. Soc. Am. J. 1989, 53 (3), 971–977. 7. Arnalds, O.; Hallmark, C.T.; Wilding, L.P. Andisols from four different regions of Iceland. Soil Sci. Soc. Am. J. 1995, 58 (1), 161–169. 8. Arnalds, O.; Kimble, J. Andisols of deserts in Iceland. Soil Sci. Soc. Am. J. 2001, 65 (6), 1778–1786. 9. Hewitt, A.E. New Zealand Soil Classification, 2nd Ed.; Landcare Research Science Series; Manaaki Whenau Press: Lincoln, New Zealand, 1998; Vol. 1. 10. Van Vliet-Lanoe, B.; Bourgeois, O.; Dauteuil, O. Thufur formation in northern Iceland and its relation to Holocene climate change. Permafr. Periglac. Process. 1998, 9 (4), 347–365. 11. Arnalds, O.; Thorarinsdottir, E.F.; Metusalemsson, S.; Jonsson, A.; Gretarsson, E.; Arnason, A. Soil Erosion in Iceland; Soil Conservation Service and Agricultural Research Institute: Reykjavik, Iceland, 2001. Translated from book published in Icelandic in 1997. Available on www.rala.is=desert.
Animals and Ecosystem Functioning Alan J. Franzluebbers United States Department of Agriculture-Agricultural Research Service (USDA-ARS), Watkinsville, Georgia, U.S.A.
INTRODUCTION Soil animals (i.e., fauna) are represented by a diverse array of creatures living in or on soil for at least a part of their life cycle. Many animals have influences on soil properties, but should not be considered soil dwellers since only a minor portion of their life cycle is spent in the soil (Fig. 1). Based on body size, soil animals can be divided into three categories: 1. microfauna (2 mm width) including millipedes, spiders, ants, beetles, and earthworms Soil animals can also be classified according to where they inhabit the soil. The aquatic fauna (e.g., protozoa, rotifers, tartigrades, and some nematodes) live primarily in the water-filled pore spaces and surface water films covering soil particles. Earthworms are divided into species that occupy the surface litter of soil (epigeic), that are found in the upper soil layers (endogeic), or that burrow deep into the soil profile (anecic). A further classification of five groups of soil animals is based on feeding activity, which can be useful in distinguishing how different groups affect soil ecosystem functions: 1. Carnivores feed on other animals. This group can be subdivided into: i) predators (e.g., centipedes, spiders, ground beetles, scorpions, ants, and some nematodes), who normally engulf and digest their smaller prey and ii) parasites (e.g., some flies, wasps, and nematodes), who feed on or within their typically larger host organism. 2. Phytophages feed on living plant materials, including those that feed on above-ground vegetation (e.g., snails and butterfly larvae), roots (e.g., some nematodes, fly larvae, beetle larvae, rootworms, and cicadas), and woody materials (e.g., some termites and beetle larvae). Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001731 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
3. Saprophages feed on dead and decaying organic material and include many of the earthworms, enchytraeids, millipedes, dung beetles, and collembola (or springtails). Saprophages are often referred to as scavengers, debris-feeders, or detritivores. 4. Microphytic feeders consume bacteria, fungi, algae, and lichens. Typical microphytic feeders include mites, collembola, ants, termites, nematodes, and protozoa. 5. Miscellaneous feeders are not restrictive in their diet and consume a range of the previously mentioned sources of food. This group includes certain species of nematodes, mites, collembola, and fly larvae. The arrangement of these feeding groups can be visualized as a soil food web with multiple trophic levels, beginning with the autotrophic flora (Fig. 2). Trophic levels describe the order in the food chain. The first trophic level is composed of photosynthetic organisms, including plants, algae, and cyanobacteria, which fix CO2 from the atmosphere into organic compounds. Organisms that consume the photosynthesizers are in the second trophic level, which includes bacteria, actinomycetes, fungi, root-feeding nematodes and insects, and plant pathogens and parasites. The third trophic level feeds on the second trophic level, including many of the dominant soil animals, including bacterial- and fungal-feeding arthropods, nematodes, and protozoa. The soil food web can be continued to include various vertebrates, including amphibians, reptiles, and mammals.
SPATIAL DISTRIBUTION OF SOIL ANIMALS Soil animals are not uniformly distributed in soil. Unlike the soil microflora, which could be considered ubiquitous, the proliferation of soil animal communities is more sensitive to environmental disturbances and ecological interactions. Gross climatic differences afford opportunities for unique assemblages of organisms. Even within a specific climatic region, large differences occur in the community of organisms present based upon type of vegetation, soil, availability 109
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Animals and Ecosystem Functioning
Fig. 1 Categories of soil animals defined according to degree of presence in soil, as illustrated by some insect groups. (From Ref.[1].)
of water, land use, and presence of xenobiotics. Within the confines of a seemingly uniform pedon, ‘‘hot spots’’ of soil organism activity can be isolated based on localized availability of resources and environmental conditions (Fig. 3).
2.
3. INFLUENCE OF SOIL ANIMALS ON SOIL FUNCTIONS Decomposition and Nutrient Cycling Soil animals work directly and indirectly with the soil microflora (i.e., bacteria, actinomycetes, fungi, and algae) to decompose organic matter and mineralize nutrients.[3] The primary consumers of organic materials are the soil microflora. Soil animals, like many of the microflora, are heterotrophs and therefore consume organic materials to gain energy for growth and activity. Soil animals make important contributions to decomposition by
4. 5.
6.
7.
activities of other organisms, especially microorganisms; consuming resistant plant materials that would decompose slowly otherwise, such as wood, roots, and dung, and transforming these materials into more decomposable constituents; dispersing soil microorganisms (i.e., inoculation) within the soil profile by transporting them on their bodies and through their intestinal tracts; creating burrows in soil to increase aeration, which stimulates microbial activity; transporting organic materials from the soil surface to deeper in the soil profile, thereby improving environmental conditions for decomposition and increasing biological interactions deeper in the soil profile; consuming bacteria and fungi, thereby releasing nutrients and stimulating the regeneration of microbial populations; and providing unique food sources themselves for consumption by other soil fauna and microflora.
1. shredding organic materials, thereby exposing a greater surface area for enhancing the Water Cycling
Fig. 2 Generalized diagram of a soil food web.
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Soil animals are active participants in the formation of soil structure, which is an important characteristic that influences water infiltration, soil water retention, and percolation.[4] The biochemical activity of soil organisms transforms organic materials into soil-stabilizing cementing agents, which bind the primary soil particles (i.e., sand, silt, and clay) into aggregates. In addition, the burrowing activity of soil animals creates larger pores alongside water-stable aggregates to increase total porosity of soil, which aids water flow without decreasing overall water retention capacity and improves the plant rooting environment. Both aggregates and porosity are important components of soil structure. Poor soil structure due to
Animals and Ecosystem Functioning
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Fig. 3 Key locations of soil organism activity. (From Ref.[2].)
disruption of aggregates, which fills pores with disaggregated primary particles and causes crusting of the soil surface, results in more rainfall that runs off land (i.e., less infiltration), potentially carrying with it sediment, nutrients, and pesticides that can contaminate surface waters. Reduced infiltration with poor aggregation reduces available water for plant growth (i.e., reduces net primary productivity and the potential to fix atmospheric CO2) and reduces percolation of water through the soil profile, essential for purification and recharge of groundwater. Those animals that create burrows in soil also create conduits for water movement through the soil profile. These biopores can be important for improving water percolation and improving rooting below claypans and other restrictive soil layers. Many different soil animals deposit fecal pellets, which become stable soil aggregates when the organic material is mixed with soil mineral particles. These aggregates are able to retain more water because of the high water-holding capacity of soil organic matter.
Pest Control Intense competition among soil organisms keeps an ecosystem healthy by preventing one organism from becoming dominant. Potential plant pathogens,
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such as root-feeding nematodes, are often held below damaging levels because of consumption by predatory nematodes and arthropods. With a healthy food web rich in species diversity, the predatory activity of many arthropods can keep crop pests below economic thresholds.
Impact of Key Soil Animals Earthworms Earthworms are well-known soil animals inhabiting many environments, most prominently found in moist-temperate ecosystems. As earthworms ingest organic materials and mineral particles, they excrete waste as casts, which are a particular type of soil aggregate that is rich with organic matter and mineralizable nutrients. It is estimated that a healthy population of earthworms can consume and aerate a 15 cm surface of soil within one or two decades. Anecic or deepburrowing species of earthworms can create relatively permanent vertical channels for improving root growth and water transport. Important attributes of earthworm activities are increased surface soil porosity, enhanced water infiltration and nutrient cycling, and distribution of organic matter within the soil profile to increase soil microbial activity.
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Termites Termites are important soil animals in grasslands and forests of tropical and subtropical regions. They often build mounds by excavating subsoil and depositing it above ground to build a city of activity with a complex social system. Termites are able to decompose cellulose in wood because they harbor various microorganisms (protozoa, bacteria, or fungi) to aid in decomposition. Better drainage and aeration of termite mounds may be beneficial to nearby plant growth in soils with a high water table. Stable macrochannels created by termites can improve water infiltration into soils that otherwise would form impermeable surface crusts. Protozoa Protozoa are single-celled animals that generally consume bacteria and soluble organic matter. Protozoa are more numerous in marine and freshwater environments, but do occur widely in water films of many soils.[5] Their principal soil function is predation on soil bacteria, which releases nutrients for potential plant uptake; increases decomposition and soil aggregation by stimulating their bacterial prey; and prevents some bacterial pathogens from developing on plant roots.
SOIL BIODIVERSITY There has been a great deal discovered about soils and the organisms that live in them, yet it is estimated that 1 m in height and >2 m diameter.[2] Ant nests consist of underground, branched networks of galleries and chambers. Surficial chambers are connected to lower chambers by vertical galleries with branching lateral galleries. Galleries and chambers vary in size and number, depending upon the species of ant. For example, Lasius neoniger, an abundant ant species in temperate North America, constructs tubular galleries of 1.5–5.0 mm diameter and chambers of 10– 20 mm diameter and 30–50 mm length. The volume of L. neoniger nests ranges from 20–250 cm3 and the nests are confined to the upper 70 cm of soil.[3] Other species construct nests to depths ranging from 50 cm to greater than several meters, depending upon species-specific behavior, soil type, and landscape position. Soil profile mixing, texture, physical and chemical property modification of mound soils, soil macroporosity, and geomorphological attributes of ant nest mounds vary with species-specific colony longevity, body size, and numbers of workers of a colony, soil type, and landscape position. The pedturbation effects of ants therefore depend upon the species composition of the ant community, geomorphic history, soil properties, and topographic position of a landscape unit. Because most studies concerning the effects of ants on soils have focused on one or two species, a comprehensive analysis of the combined effects of all ant species on the soils of an ecosystem cannot be made.
In areas that are periodically flooded or where the water table is close to the surface, some species of soil-nesting ants build mounds that create favorable microhabitats for themselves and also a habitat for some species of plants that are confined to the aerated soils of the ant mounds. Soil-nesting ants create hummock microtopography in some wet meadow fens and tropical wet savannas.[4] In the Chaco region of South America (parts of Paraguay, Bolivia, Argentina, and Brazil), nest mounds of Camponotus punctulatus occur at densities of between 200 and 1000 mounds=ha. These conical mounds average a height of 0.62 cm (with a maximum of 1.85 m ) with a mean basal diameter of 1.2 m. The mound soils are lighter textured than surrounding soils, reflecting the amount of materials transported from surrounding subsurface soil during mound construction.[5] Formica podzolica mounds in a Montana fen are thought to contribute to the hummock-hollow microtopography of peat lands. Abandoned F. podzolica mounds provide drier, warmer microsites that are enriched with some soil nutrients.[4] The mounds of L. flavus contribute to the microtopography of some European grasslands and salt marshes.[6] Mima-type earth mounds up to a height of 1.5 m with a diameter of 20 m in Buenos Aires Province, Argentina, are produced by horizontal translocation of soil to the colony sites of black fire ants, Solenopsis richteri. Continued occupation of the mounds by successive generations of ants gradually increases the size of the mounds to mima-type size.[7] Ants (Formica spp. and Myrmica spp.) are important agents in the process of development and maintenance of hummock microtopography of subarctic peatlands. Hummock retrogression is accelerated by the tunneling activity of ants.[8]
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042632 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
HETEROGENEITY OF PHYSICAL AND CHEMICAL PROPERTIES OF THE SOIL Many species of ants alter the texture and chemistry of the soil in the nest mounds. The nutrients most 117
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frequently reported to be at higher concentrations in ant mound soils include nitrogen, phosphorus, potassium, calcium, magnesium, manganese, and iron.[9] The effect of soil-nesting ants on soil nutrient patchiness and on vegetation varies as a function of landscape position, soil type, and the biology of the ant species. Nutrient enrichment of mound soils has been reported for several species of seed-harvesting ants and omnivorous species of ants that collect seeds, prey on insects, or collect insect carrion. Species of soilnesting ants that enrich the nutrient content of mound soils are characterized by relatively long-lived colonies (>5 years) and the behavior of depositing chaff and unwanted insect parts on and around the nest mound or disk. Nutrient enrichment of mound soils by a species may not occur on all soils on a watershed or landscape. For example, Pogonomyrmex rugosus nest disks in desert shrubland and mixed shrub-grassland were nutrient enriched, but the nest disks of this species in a piedmont grassland were not nutrient enriched.[10] Formica spp. mounds in forest were nutrient enriched, but Formica spp. mounds in meadows and grasslands were not.[11] The variability in soil nutrient enrichment of ant mounds has been documented in several species of leaf-cutting ants. In remnant Cerrado (woodlandsavanna), Brazil, leaf-cutting ants (Atta spp.) had no detectable effect on nutrient enrichment.[12] In northern Patagonia, soils associated with the leaf-cutting ant, Acromyrmex lobicornis, had higher concentrations of nitrogen, phosphorus, and organic matter than reference soils.[13] The location of nutrient-rich organic refuse produced by leaf-cutting ant colonies varies among species. A. cephalotes deposit organic refuse in subterranean chambers, whereas A. colombica place organic refuse on the soil surface near the nest. The location of organic refuse is a major factor affecting nutrient concentrations and the composition, abundance, and activity of soil microflora and microfauna.[14] In the Orinoco Llanos savanna, Venezuela, A. laevigata nests had higher concentrations of nitrogen, magnesium, calcium, and organic carbon, but other soil nutrients and properties were not affected by ant mounds.[15] In an Australia vertisol, ant nest soils had greater concentration of coarse and particulate organic matter, lower fine particulate soil organic matter (SOM) =coarse particulate SOM ratios, larger sand content, and lower clay content than surrounding soils.[16] Nutrient enrichment of nest mound soils of funnel ants (A. barbigula) was attributed to entrapment of organic materials around the nest entrances. Re-excavation of nest chambers after rainfall buries trapped litter, resulting in higher concentrations of nitrogen, organic matter, and some cations compared to nest-free soils.[17] In humid tropical savanna, ant mounds of
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Ants
Camponotus spp. had higher clay and coarse sand content than surrounding soils.[9] Even exotic or alien species of ants change the chemical and physical properties of nest mound soils. Mounds of imported fire ants (S. invicta) had higher concentrations of clay, phosphorus, and potassium, and lower concentration of soil organic matter than reference soils. The effect of S. invicta on calcium concentrations relative to reference soils was dependent upon the characteristics of the unmodified soil.[18] Ants change the nutrient concentration of mound soils, but the physical and chemical properties of mound soils can also affect mineralization processes. Nitrogen mineralization rates were reduced in nest mound soils in moss-sedge, sedge, and alder peat habitats.[19]
SOIL TURNOVER The longevity and turnover rates of nests and nest mounds of ants in a community frequently follow a distribution gradient from high turnover (10 years). The importance of ants in the transport of subsurface horizon materials to the surface varies with the density and diversity of the ant community on a landscape unit. In Chihuahuan Desert grasslands, soil-nesting ants are an order of magnitude more abundant on sand and sandy loam soils than on fine-textured soils. Ants were estimated to move between 21.3 and 85.8 kg=ha=yr on sandy and sandy loam soils and between 0.1 and 3.4 kg=ha=yr on clay and clay-loam soils.[20] The estimated annual soil turnover by ants in an Atriplex vesicaria shrubland in the semi-arid region of Australia was 350– 420 kg=ha=yr.[9] Soil that is excavated by ants in the construction of galleries and chambers and deposited on mounds around nest entrances is generally eroded by water and wind within a year unless the mound is protected from raindrop splash erosion by gravel, stones, or wood fragments. Nest mound soils may be replenished by the belowground expansion of galleries and chambers. Ant nest mounds in sparsely vegetated arid regions are prone to wind erosion. On an Australian aeolian soil, funnel ants’ (Aphaenogaster barbigula) nests were active for approximately nine months and the ants changed location approximately twice per year. Soil transport was estimated to be 33.6 kg=ha, and it was estimated that 92% of the soil volume would be turned over by these ants in 100 years.[21] In Western Australia, ant communities on gray soils of semi-arid woodlands were estimated to turnover 46.5 kg ha=yr and on yellow soils, the soilnesting ant community was estimated to turnover 22.3 kg=ha=yr.[22] In a humid savanna environment, one abundant ant species, Paltothyreus tarsatus, was
Ants
estimated to transport approximately 30 g=m2=yr of sand particles and soil aggregates. This ant species increased the concentrations of clay, carbon, iron oxides, and coarse sand in the A horizon.[9] The amount of soil transported to the surface by Pognomyrmex occidentalis in pinon-juniper woodland and ponderosa pine forest was estimated to be 650 kg=ha.[23] Soil turnover by the ant community in New England forest soil was estimated to be over 50 kg=ha=yr. It was concluded that the translocation of B-horizon materials to the soil surface by soilnesting ants was an important process in podzol formation in New England forest soils.[24] Some long-lived species of soil-nesting ants relocate their nests one or more times a year. Construction of new nests results in the transport of a volume of soil equal to the volume of galleries and chambers to the soil surface. Most of that soil originates in lower soil horizons and contributes to soil profile homogenization. The relocation of nests by some species of ants results in lower estimates of soil turnover than occurs in some environments.
SOIL WATER RELATIONS The structure of nests of soil-nesting ants provides extensive macroporosity to the soil in which the nests are constructed. The macropores constructed by ants affect rates of infiltration and rates of percolation. In some environments, extremely high densities of nest entrances can have a dramatic effect on infiltration. In semi-arid Western Australia, ant biopores were found to transmit water down the soil profile only when the soil was saturated and water was ponding on the surface.[25] On aeolian sand soils in Australian semi-arid woodland, densities of nest entrances of funnel ants (A. barbigula) were estimated at 88,000 per hectare. Steady-state water infiltration on soils with nest entrances averaged 23.3 mm=min, in comparison to an infiltration rate of 5.9 mm=min on nestentrance-free soil.[26] In semi-arid woodland of Eastern Australia on red earth soil, ponded steady-state infiltration averaged 1026 mm=hr on soil with nest entrances of A. barbigula, but only 120 mm=hr on soils without nest entrances.[27] Bulk flow along nest galleries provides an important route of recharge of deep soil moisture in arid and semi-arid environments. Ant gallery macropores are not always avenues for bulk flow. In a study of a mesic Typic Quartzipsamment, there was no preferential flow down ant galleries. The lack of an effect on hydraulic conductivity was attributed to the sandy soil.[28] In another study of a sandy soil, the estimated saturated soil matrix hydraulic conductivity of nest burrows was approximately
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eight times smaller than that of the bulk sandy soil. This reduction in hydraulic conductivity was attributed to the ants’ in-filling of gallery walls with fine materials.[28]
EFFECTS ON OTHER SOIL BIOTA Soil around relatively long-lived ant colonies may be enriched with microflora, microfauna, and mesofauna. The soils of nest disks of western harvester ants, P. occidentalis, are enriched with vesicular-arbuscular mycorrhizal fungi.[29] In areas of North America dominated by the red imported fire ant, S. invicta, the species composition and abundance of soil yeast within mounds are altered by changes in soil properties produced by fire ants.[30] Mound soils of F. aquilonia are dominated by bacteria-feeding microfauna and have a higher microbial biomass than the surrounding soils.[31] Species-specific differences in the effect of ants on soil microflora of mounds are related to the feeding strategies of the species and nest architecture. Three ant species, M. scabrinodis, L. niger, and L. flavus, differ greatly in foraging strategies and methods of mound construction. Microbial functional diversity and evenness were higher in mound soils of M. scabrinodis and L. niger than in reference soils but were not different from reference soils in the mounds of L. flavus. Different functional groups of microorganisms were activated in the mounds of the different species. Carbon mineralization was higher in mound soils of all three species.[32]
CONCLUSIONS Ants contribute to heterogeneity in soil properties by the construction of subterranean nests and by accumulating organic materials in and around nests. Construction and maintenance of nests affect soil turnover, macroporosity, and mixing of soil profiles. Foraging and food processing behaviors affect soil nutrient concentrations and soil microflora and microfauna. The magnitude of the effects of ants on soils is dependent upon soil type and topographic position.
REFERENCES 1. Holldobler, B.; Wilson, E.O. The Ants; The Belknap Press of Harvard University Press: Cambridge, 1990. 2. Green, W.P.; Pettry, D.E.; Switzer, R.E. Formicarious pedons, the initial effect of mound-building ants on soils. Soil Survey Horizons 1995, 39 (2), 33–44. 3. Wang, D.; McSweeney, K.; Lowery, B.; Norman, J.M. Nest structure of the ant Lasius neoniger emery and
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5.
6. 7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
Ants
its implications to soil modification. Geoderma 1995, 66 (3–4), 259–272. Lesica, P.; Kannowski, P.B. Ants create hummocks and alter structure and vegetation of a montana fen. Am. Midl. Nat. 1998, 139 (1), 58–68. Pire, E.F.; Torres, P.F.; Romagnoli, O.D.; Lewis, J.P. The significance of ant-hills in depressed areas of the Great Chaco. Rev. Biol. Trop. 1991, 39 (1), 71–76. King, T.J. Ant-hills and grassland history. J. Biogeog. 1981, 8, 329–334. Cox, G.W.; Mills, J.N.; Ellis, B.A. Fire ants (Hymenoptera : Formicidae) as major agents of landscape development. Environ. Entomol. 1992, 21 (2), 281–286. Luken, J.O.; Billings, W.D. Hummock-dwelling ants and the cycling of microtopography in an Alaskan peatland. Can. Field Nat. 1986, 100 (1), 69–73. Lobry de Bruyn, L.A.; Conacher, A.J. The role of ants and termites in soil modification a review. Aust. J. Soil Res. 1990, 28 (1), 55–95. Whitford, W.G.; DiMarco, R. Variability in soils and vegetation associated with harvester ant (Pogonomyrmex rugosus) nests on a Chihuahuan desert watershed. Biol. Fertil. Soi. 1995, 20, 169–173. Culver, D.C.; Beattie, A.J. Effects of ant mounds on soil chemistry and vegetation patterns in a Colorado montane meadow. Ecology 1983, 64 (3), 485–492. Schoereder, J.H.; Howse, P.E. Do trees benefit from nutrient rich patches created by leaf-cutting ants? Stud. Neotrop. Fauna Environ. 1998, 33 (2–3), 111–115. FarjiBrener, A.G.; Ghermandi, L. Influence of nests of leaf-cutting ants on plant species diversity in road verges of Northern Patagonia. J. Veg. Sci. 2000, 11 (3), 453–460. FarjiBrener, A.G.; Medina, C.A. The importance of where to dump the refuse: seed banks and fine roots in nests of the leaf-cutting ants. Atta cephalotes A. colombica. Biotropica 2000, 32 (1), 120–126. Brener, A.G.F.; Silva, J.F. Leaf-cutting ants and forest groves in a tropical parkland savanna of Venezuela: facilitated succession. J. Trop. Ecol. 1995, 11 (4), 651– 669. Hulugalle, N.R. Effects of ant hills on soil physical properties of a vertisol. Pedobiology 1995, 39 (1), 34–41. Eldridge, D.J.; Myers, C.A. Enhancement of soil nutrients around nest entrances of the funnel ant Aphaenogaster barbigula (Myrmicinae) in semi-arid Eastern Australia. Aust. J. Soil Res. 1998, 36 (6), 1009–1017. Green, W.P.; Pettry, D.E.; Switzer, R.E. Impact of imported fire ants on the texture and fertility of Mississippi soils. Comm. Soil Sci. Plant Anal. 1998, 29 (3–4), 447–457.
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19. Petal, J. The influence of ants on carbon and nitrogen mineralization in drained fen soils. Appl. Soil Ecol. 1998, 9 (1–3), 271–275. 20. Whitford, W.G.; Forbes, G.S.; Kerley, G.I. Diversity, spatial variability, and functional roles of invertebrates in desert grassland ecosystems. In The Desert Grassland; McClaran, M.P., Van Devender, T.R., Eds.; University of Arizona Press: Tucson, 1995; 152–195. 21. Eldridge, D.J.; Pickard, J. Effects of ants on sandy soils in semiarid Eastern Australia. 2. Relocation of nest entrances and consequences for bioturbation. Aust. J. Soil Res. 1994, 32 (2), 323–333. 22. Lobry de Bruyn, L.A.; Conacher, A.J. The bioturbation activity of ants in agricultural and naturally vegetated habitats in semiarid environments. Aust. J. Soil Res. 1994, 32 (3), 555–570. 23. Carlson, S.T.; Whitford, W.G. Ant mound influence on vegetation and soils in a semiarid mountain ecosystem. Am. Midl. Nat. 1991, 126 (1), 125–139. 24. Lyford, W.H. Importance of Ants to Brown Podzolic Soil Genesis in New England; Harvard Forest Paper No. 7; 1963; 1–18. 25. Lobry de Bruyn, L.A.; Conacher, A.J. The effect of ant biopores on water infiltration in soils in undisturbed brushland and farmland in a semi-arid environment. Peodobiology 1994, 38 (3), 193–207. 26. Eldridge, D.J. Effect of ants on sandy soils in semiarid Eastern Australia: local distribution of nest entrances and their effect on infiltration of water. Aust. J. Soil Res. 1993, 31 (4), 509–518. 27. Eldridge, D.J. Nests of ants and termites influence infiltration in a semiarid woodland. Pedobiology 1994, 38 (6), 481–492. 28. Wang, D.; Lowery, B.; Norman, J.M.; McSweeney, K. Ant burrow effects on water flow and soil hydraulic properties of sparta sand. Soil Till. Res. 1996, 37 (2–3), 83–93. 29. Friese, C.F.; Allen, M.F. The interaction of harvester ants and vesicular arbuscular mycorrhizal fungi in a patchy semiarid environment: the effects of mound structure on fungal dispersion and establishment. Funct. Ecol. 1993, 7 (1), 13–20. 30. Ba, A.S.; Phillips, S.A.; Anderson, J.T. Yeasts in mound soil of the red imported fire ant. Mycol. Res. 2000, 104 (8), 966–973. 31. Laasko, J.; Setala, H. Composition and trophic structure of detrital food web in ant nest mounds of Formica aquilonia and in the surrounding forest soil. Oikos 1998, 81 (2), 266–278. 32. Dauber, J.; Wolters, V. Microbial activity and functional diversity in mounds of three ant species. Soil Biol. Biochem. 2000, 32 (1), 93–99.
Arab Traditional Soil Classification: A Moroccan Case Mohamed Sabir Hassan Ben Jelloun National School of Forest Engineers, Tabriquet, Sale, Morocco
INTRODUCTION Soil science, a relatively new discipline, compared to other fields, such as botany, biology, zoology, and mineralogy, is lacking an internationally accepted taxonomic system. Traditionally, a local scientific system of soil classification was lacking in most countries of the Arab world. However, soils were mostly designated by vernacular names that stem from local agricultural practices and soil use.
BACKGROUND Different systems of soil classification have been developed throughout the world.[1] In the Maghreb Arab countries (Morocco, Algeria, and Tunisia), the first efforts related to soil classification were initiated in 1934 by Del Villar, who was the president of the Mediterranean subcommission of the 1st International Society of Soil Science.[2] His principal and most important pedological studies were conducted in Morocco. At present, vernacular names are still used among farmers and even among agricultural scientists, and detailed soil classification system are inspirations from the ones developed in western Europe, Canada, and the United States of America, especially the systems of soil classification adopted by the Commission of Pedology and Cartography of Soil of France (CPCS, 1967),[3] FAO=UNESCO. Soils of the World (ELSEVIER=ISRIC, 1989),[4] Soil Taxonomy (1975)[5] and the World Reference Base (1994).[6] The object of this entry is to present a brief review about the soil classification scheme used in some areas of Morocco.
ANCIENT ARAB SOIL CLASSIFICATION Knowledge about land and agricultural practices stems from before Roman times. Men in ancient times have already used many of our farming practices nowadays (manuring, liming, and crop rotations with legumes).[7] Most of the actual knowledge farmers used during the long period from the fall of Roman civilization Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120017330 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
to the French Revolution and for some time afterward was the local knowledge of farmers. At the time where the people of Europe were disorganized and lived in a dark age of diseases, famine, and war for more than a thousand years, the Arabian culture flourished in the Near East, northern Africa, and southern Spain, where farming was reasonably good, especially under irrigation. Some of soil classification systems and farming practices were well explained in the handbook of agriculture prepared by Ibn-al-Awam,[7] with a Moorish scholarship, in the 12th century. Ibn-al-Awam’s[8] book of agriculture classified different land types according to their agricultural qualities as follows:
Black earth: A warm earth that gives high agricultural yields;
Red earth: A moderately warm earth with moderate agricultural yields;
Yellow earth and white earth: A cold earth that gives low agricultural yields;
Dry earth: It has two species or divisions: – Sandy earth: It has a low fertility level; – Muddy earth: It has a marly–clay texture, it is sticky and plastic, and it becomes very hard and very compact when dry.
MOROCCAN VERNACULAR SOIL NAMES Soil classification was introduced for the first time to the Mediterranean region in 1925 through the efforts of Spanish pedologist Del Villar (Table 1).[9] Previously, most of the soil types were designated by their color, texture, structure, degree of fertility, and water-holding capacity despite the fact that their meaning may differ from a region to another. In the northern humid regions, soils are distinguished by their fertility. Contrariwise, in the southern arid regions, soils are distinguished by their water-holding capacity following irrigation. Among the Maghreb West Arab countries, Morocco, Algeria, and Tunisia show climatic, geologic, and geomorphologic similarities.[10] Therefore, some of the vernacular soil names (Table 2) used in Morocco may, to some extent, be encountered in Algeria and Tunisi. 121
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Table 1 Del Villar soil classification system Soil types 1-Homocyclic type
Soil cycles 1.1. Sialferric cycle: Soil dynamics are dominated by colloidal silicon and aluminum and by ferrous sesquioxides.
Soil sectors S1. Oxyhumic sector: Unsaturated soil with acid humus. Leaching or epigenic metabolism is strong (e.g., gley soil). S2. Siallic sector: Humus is not acidic, the ratio SiO2=Al2O3 > 2, pH 2; Fe2O3 is high. S4. Allitic sector: SiO2=Al2O3 is very low. Leaching is important. Podzolization is possible. Ferruginous accumulation is possible (laterite soil).
1.2. Calcareous cycle: Pedogenic processes related to calcareous parent rock or carbonate-rich material are dominant. Leaching of carbonate may give K horizon at depth. Distinguished soils are: Soil with AC profile; Soil with AKC profile (rendzina soil, terra-rossa soil). 1.3. Sodic cycle: Pedogenic processes are dominated by sodium (Na). S1. Saline sector: Na is in chloride form to which other soluble salts and gypsum are added. Saline soils may be epigenic or hypogenic. Epigenic metabolism of Na (leaching) is dominant (e.g., coast marshes). Hypogenic metabolism: Salts are lifted from below to the surface. Examples are: Thermal sources; Salty lagoons; Black saline soil: gley solontchak soil; Local deposited salt sebkhas of Arab countries; Saline soil with surface crust; Soil with salt at depth (infrasaline soil); Soil with low salt concentration at surface (subsolontchak soil). (Continued)
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Table 1 Del Villar soil classification system (Continued) Soil types
Soil cycles
Soil sectors S2. Alkaline sector: Hypogenic metabolism process is low, but endogenic process resulting from precipitation, epigenic process, and percolation is dominant (solonetz soil).
1-Heterocyclic type: Pedogenic metabolism responsible for soil type is not based on known chemical process. Chemical characteristics are mixed or variable; it is the regime which is responsible of soil type individualization. Distinguished soils are: Nonsodic–hydro-epigenic soil (alluvial soil); Soil with subamphigenic or subbalanced regime (prairie soil); Soil with amphigenic or balanced regime (chernosium soil); Soil with hydro-hypogenic regime (clayey–gley soil); Soil with hydro-hypogenic calcification; Oligogenic soil (Thin A horizon); Ambrogenic or holohypogenic soil ¼ crypto-hypogenic and pheno-hypogenic soil (soils of desert climate. Below ground water table and lithic material are the dominant genetic factors.); Mixed transitional soil types.
In Morocco (Fig. 1), several local soil names are used. Region I: North Western Rif Mountains Ferich: A thin soil formed on pelitic rock material with high percentage of flysch plates. Rmel and ferich: Complex soil, mixture of sandy (rmel) and ferich materials. Abiad: White soil color (abiad means white), developed on marl and marly–flysch material. Hajar: Nonsoil with sandstone outcrops (hajar means rock outcrop and stones). Rmel or rmel jayef: Sandy soil (rmel means sand) with red-yellowish color. This soil has low fertility, sometimes has small rock grains, and is not hard when dry. Teine: Vertic soil with high expanding clay content and high water retention (teine means clay). Hamri: Red soil with high content of ferric oxides. Amlil: Lithic calcareous soil with generally white color. Sahl: Less developed soil on alluvial sediments. Ard kbira: Black soil with high fertility level and high agricultural productivity and is suitable for
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all agricultural uses with low rock content and low water infiltration rate (ard kbira means big soil). Toiress: Brown soil with low fertility but still good crop production. Rock content of this soil is moderate. Fairly hard when dry with particular texture. Region II: Temara (South of Rabat on the Coast Side) Rmel: Sandy soil with brown color. Highly permeable, not hard when dry, has low percent of stones, and may reach 2-m depth. Hamri: Red soil with high content of ferric oxides in mixture with clay; it is weakly permeable, hard, has low percentage of stones, and may reach 1-m depth. El hassa: Grey soil with high percentage of stones, fairly permeable, and stones may reach 0.5-m depth. Biad: White-colored soil with low agricultural productivity and good water permeability. Hrach: Yellow-colored soil with low agricultural productivity, good water permeability, and some stones (hrach means rough).
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Table 2 Vernacular soil names and their equivalent in soil taxonomy Vernacular soil names a
Soil taxonomy equivalent names a
Ferich (R1 ), Hajar (R1), Sgguine (R5 ), Salsale (R5), Azegzou (R7a)
Entisols
Rmel (R3a and R5)
Psaments (Entisols)
Rmel (R1), Abiad (R1), Amlil (R1), Sahl (R1)
Udepts (Inceptisols)
Rmel jayef (R1)
Mixed Entisol–Udepts
Biad (R2a), El Hrach (R5)
Xerocrepts (Inceptisols)
Hrach (R2 and R3)
Stony xerocrepts
Biadi (R3)
Xerocrepts over marl
Teine (R1)
Pelluderts (Vertisols) a
Tirs (R3), Tirst (R4 ), Tirste (R5)
Chromoxererts (Vertisols)
Hrach (R6a), Itikki or Hamri (R6), Tamakalte (R6), Terrist (R7)
Orthids (Aridisols)
Amarigh (R7)
Salorthids (Aridisols)
Azougakh (R7), Amerdoum mouharmel (R7)
Argids (Aridisols)
Ard Kbira (R1), Toires (R1)
Vertic Udolls (Mollisols)
Rtab (R4), Hamri (R5)
Xerolls (Mollisols)
Safra (R4)
Aquolls (Mollisols)
Rmel (R2 and R4), Hamri (R2, R3), and R5), Ahamri (R4)
Xeralfs (Alfisols)
a
R1, R2, R3, R4, R5, R6, and R7 are Moroccan regions where local soil names are used.
Region III: Romani (South East of Rabat) Tirs: Black to dark brown soil with high fertility, needs large quantities of water for irrigation, has good agricultural potential, contains high percentage of expanding clay and low stones, has good permeability, and is resistant to erosion. Hrach: Grayish soil that requires less water with medium agricultural potential, is slightly permeable, and has large particles and stones. Hamri: Red soil that has particles of loam and clay diameter in mixture with stones, needs much water for irrigation with very good agricultural potential. Biadi: White soil with dust and stone on the surface. Rmel: Brownish soil with sandy texture, high permeability, and low water-holding capacity, no stones, and deep. Region IV: Midelt (High Moulouya Region) Ahamri: Red soil that has clayey texture, compact with no stones, a high water-holding capacity, gets rapidly dry and warm, and has good crop production capacity. Tirst: This soil is black, has clayey texture, is less or more compact with no stones. Water-holding capacity of this soil is fairly good, and it is good soil for agriculture. It shows more resistance to dryness than hamri. On slopes, when dry, may
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show wind erosion hazard. Parent rocks are sediments of 10-cm depth. Agricultural yields are of 1000 to 1200 kg=ha=yr (less than world average). Rtab: This is dusty soil with medium texture and no stones. It is 1 m thick, holds water for 20 to 30 days after showers or irrigation. Hrach: Hrach is dark brown compact soil with large particles and stones. It is 0.5 to 1 m thick, holds water for 8 to 10 days after showers or irrigation. Rmel: It has silver-gray color, light-sandy texture, and low water-holding capacity. Safra: Yellow calcareous soil (safra means yellow color) with clayey texture, hard, shows some water stagnation, and shallow (about 15 cm thick). Region V: Moulay Bouazza Tirste: Black soil with slightly stony–fine texture, low permeability, high water-holding capacity, shows little cracks when dry and good biomass production vegetation development. Hamri: It is a red compact soil, slightly stony texture, low to moderate water permeability, and cracks when dry. This soil needs much water for irrigation and shows medium potential for agriculture. El Hrach: This soil has reddish-gray color with stones in the surface layer, is fairly permeable, and requires low quantities of water for irrigation.
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Fig. 1 Map of Morocco, geographical situation of different regions where traditional soil names were collected (RI: North Western Rif; RII: Temara; RIII: Romani; RIV: Midelt; RV: Moulay Bou Azza; RVI: Bou Malne Daddes; RVII: Erfound).
Rmel: Yellow soil of sandy texture, with no stones, and highly permeable. Sgguine: White-colored soil with hard stony–fine texture, permeability is low and agricultural potential is poor. Salsale: Gray soil with low stones, has friable consistence, low permeability, and poor quality. Region VI: Bou Malne de Daddes (arid and Saharan region) Rmel: It has yellow soil color, fine texture with no stones, not hard when dry, fertility is medium, and water-holding capacity is very low.
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Hrach: Faint red soil, very hard stony–loamy texture, fertility is moderate, water-holding capacity is low, workability is difficult, sometimes has water stagnation, and agricultural potential is medium. Itikki or hamri: Red soil with very hard compact clayey texture, has a high water-holding capacity, its dryness is very slow, and shows a good agricultural potential. Tamakalte: Black grey soil with a fine clayey texture, resistant to dryness, has a high water retention capacity, and has a good agricultural potential.
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Region VII: Erfoud (arid and Saharan region) Terrist: White–yellow soil, without stones, no salt, and agricultural potential is low. Amarigh: Different colors of soil (white, yellow, red, and black) and has salinity problems. Azegzou: Schistous nonsoil, agriculture is not practicable. Azougakh: Red soil, may have or may have not stones, and good for agriculture. Amerdoum mouharmel: Very heavy clayey soil, dryness is very slow, and has spontaneous vegetation.
CONCLUSIONS In the Maghreb Arab world, soil science, in general, and soil classification systems, in particular, have followed the same evolution as in all the circum Mediterranean countries. In this region, agricultural practices go back to the prehistoric period, and soil names used before the development of a scientific soil classification scheme were mostly related to local agricultural practices and were based essentially on color, texture, structure, fertility, richness of stones, and water-holding capacity. In Morocco, as likely in the other countries of the Arab world, because of the multiplicity of ethnic tribes and natural conditions (climates, geological material, vegetation), most of these names are maybe the same to qualify different soils.
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Arab Traditional Soil Classification: A Moroccan Case
REFERENCES 1. Finkl, C.W. Soil classification. Benchmark Pap. Soil Sci. 1982, 1, 391 p. 2. Del Villar, E.H. Types de sol de l’Afrique du Nord; Soil Types of North Africa; Fascicule II: Tunis-Rabat, 1947; 137–288. 3. Commission of pedology and cartography of soils (CPCS). In Reprinted from Classification des Sols; INRA, Laboratoire de Ge´ologie–Pe´dologie: Paris, 1967; pp. 1, 5–13, 15. 4. FAO-UNESCO. Soils of the World; Elsevier Science Publishers B.V., 1987; ELSEVIER=ISRIC. 5. Soil Survey Staff. Soil taxonomy, a basic system of soil classification for making and interpreting soil surveys. In Agriculture Handbook No 436; Soil Conservation Service, U.S. Department of Agriculture, 1975; 754 pp. 6. Atelier sur les bases de donne´es SOTER dans les pays de l’UMA; Workshop on SOTER Data Base in UMA Countries; Organisation des Nations Unies pour l’Alimentation et l’Agriculture, Bureau Sous-Re´gional pour l’Afrique du Nord, SNEA: Tunis, 2001; 132 pp. 7. Soil, the Yearbook of Agriculture; United State Department of Agriculture: Washington, DC, 1957; 784 pp. ^ b al Fila ^ ha). 8. Ibn-al-Awam Le livre de l’agriculture (Kita In Traduction from Arab by J.J. Cle´ment-Muller Introduction of Mohammed El Faı¨z, ‘‘Thesaurus’’; Actes Sud=Sindbad, 2000; 1027 pp. 9. Del Villar, E.H. Me´thodes de Classification et Analyse des Sols. Base Scientifique Pour Leur Cartographie Harmonique Universelle; Methods of Classification and Soil Analysis. A Scientific Basis for Their Cartography; 1953; 193 pp. 10. Refleh, Ph.; Chami, A.M. Geography of the Arab World; Annahda Library: Egypt, 1962; 375 pp. Published in Arabic.
Archaeology and Soil John E. Foss University of Tennessee, Knoxville, Tennessee, U.S.A.
INTRODUCTION Geology has had a long period of interaction with archaeology, but the use of soil investigation in archaeology has a rather short history. In 1942, Nikiforoff[1] used the term archeopedology for those soil scientists working with fossil soils or paleosols. Early studies of soils at archaeologic sites were concerned mainly with soil chemical properties (e.g.,[2–4]. An early book by Cromwall[5] also played an important role in demonstrating the usefulness of soil–archaeologic interactions. The past 30 or 40 years have seen a substantial increase in the multidisciplinary effort between these two sciences and have involved more subdisciplines of soil science.
by Scudder, Foss, and Collins[9] Soil Science Society of America Special Pub. No. 44 on ‘‘Pedological Perspectives in Archaeological Research,’’[10] and articles in the Proceedings of Conferences on Pedoarchaeology[11–12] have raised pedologists’ and archaeologists’ awareness of the potential contributions of soil studies to site evaluation. The periodical Geoarchaeology: An International Journal has also been valuable in promoting earth science activity in archaeologic investigations. Some of the major pedologic contributions to field archaeology have included the following:[13]
ROLE OF SOIL SCIENCE IN ARCHAEOLOGY
As archaeologists become more interested in a complete understanding of the chronology and environmental history of sites, a multidisciplinary effort is absolutely necessary. Team members commonly include scientists from soil science, geology, botany, zoology, palynology, and other specializations. Soil science, especially the pedology area (i.e., the study of soil formation and classification), has been particularly active within the past few decades in evaluation of archaeologic sites. Pedology, geology, and other earth sciences often work in the specialized field of geoarchaeology, which means using earth science principles to study archaeologic sites. Fig. 1 shows a landscape of Tikal, Guatemala (Mayan site); this site is one of the many important archaeologic sites that has required the expertise of pedologists to help interpret chronology and land use.[6–9] The study of soils and landscapes is an integral part of many archaeologic investigations. Some federal and state regulations that require geologic and soil input on archaeologic sites have also been responsible for including earth scientists in these studies. Publications in the past decade have indicated the interest of pedologists, geologists, and archaeologists in evaluating soils and landscapes as part of overall archaeologic investigations. Publications such as ‘‘Soils in Archaeology’’ edited by V.T. Holliday,[8] ‘‘Soil Science and Archaeology’’
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001941 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
Determining site delimitation General pedologic stratigraphy Soil–landscape relationships Identification of geologic parent material Correlating soil morphology and archaeologic levels Identifying lithologic (parent material) and pedologic (soil weathering) discontinuities Approximating soil age Identifying paleosols (fossil soils) Contributing to the overall interpretation of site
In the past decade, many of the above pedologic contributions to archaeology were made during the final phase of archaeologic field work. More recently, pedologists have been more involved in phase 1 activity of archaeologic investigations. The early identification of major stratigraphic zones, preliminary analysis of landscape and soil age, and model of site development have resulted in more efficient archaeologic excavations and interpretations.
FIELD STUDIES Archaeologic sites occur in many different geologic provinces and landscape positions. Determination of the site context is thus the most important initial stage in pedoarchaeology. Geologic maps can provide general knowledge of a region, but detailed soil surveys provide the most useful introduction to a study area. These maps produced by the National Resource Conservation Service (NRCS), in cooperation with the Land Grant Institutions, are usually on a county-wide 127
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Fig. 1 Landscape view of Mayan city of Tikal, Guatemala.
basis using an air photo base with a scale of 1 : 15840 to 1 : 24000. At this scale, there is not sufficient detail to relate the morphology of individual soil mapping units to specific horizons encountered at an archaeologic site. The landscape and physiographic position of each soil mapping unit, however, are still useful in preliminary analysis of archaeologic sites. The most important and informative archaeologic sites occur in landscapes where sediment is added to a pre-existing surface, therby protecting the artifacts and soil horizons. Those buried sites may occur in the following areas or situations:
Alluvial deposition
Volcanic activity
Eolian deposition Colluvial slopes Mass movement or slumping Seismic areas Artificial deposition or destruction
These situations provide the opportunity for soil burial (subsequently termed paleosols) and archaeologic levels. The buried surfaces (A horizons) of these paleosols are particularly good sources of artifacts and living surfaces when the events above took place in the Holocene. Holliday[8] provides an excellent background in the use of paleopedology in archaeology.
Soil Morphology Soil morphology (e.g., a detailed description of soil profiles) provides the key to understanding and interpreting soils and landscapes at archaeologic sites. The unique soil morphology of a given region and site results from the weathering processes regulated by the interaction of soil-forming factors.[14] These factors are climate, biotic, geology, topography, and length of time that the weathering processes have been operating. The morphologic properties of soils usually described in excavations and their interpretation for archaeologic sites are given in Table.1 A great deal
Table 1 Morphologic properties of soils and their interpretive value at archaeologic sites Soil property
Useful interpretative features
Texture
Lithologic and pedologic discontinuities; classification of geologic materials; determination of argillic horizons; determine relative energy of alluvial sedimentation
Structure
Relative abundance of macropores and potential artifact movement; degree of development is an indicator of soil age; development of clay or organic coatings on argillic horizons (e.g., continuous clay coatings on pedologic faces indicate 10,000 years of development while discontinuous coatings may indicate 4000–5000 years of weathering in southeastern U.S.)
Color
Indicator of organic matter and free iron content; classification of sediments; delineation of horizons; drainage characteristics (redoximorphic features)
Boundary
Abrupt boundary indicator of Ap (plow zone) or recent deposition; boundary becomes more diffuse with age
Consistence
Indicator of structural development, cementation, or consolidation (e.g., recent alluvium usually very friable or loose)
Clay coatings
Coatings on peds or in pores indicate state of development and age
Carbonate
Secondary CaCO3 leaching, coatings, pore filling, and cementation can provide soil age estimates and climatic implications
Horizon identification
Indicates many weathering processes occurring in profile, e.g., A ¼ organic matter accumulation; E ¼ leached zone; Bt ¼ argillic horizon with minimal 4,000 year age; distinguish natural vs. artificial horizons; horizon thickness (solum) is a measure of length of weathering time; diagnostic horizons useful indicator for archaeological interpretation (e.g., argillic, cambic, fragipan, spodic, etc.)
(Modified from Ref.[13].)
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Archaeology and Soil
of experience and technique is needed to provide an accurate and informative soil description. Evaluation of the age of soils, for example, requires an integration of all the morphologic features that are detailed in Table 1. Certain soil horizons provide general age estimates based on the length of time needed for weathering processes to develop specific features (e.g., argillic horizons). As noted in Table,1 a minimal argillic horizon can form in 4,000 years. Other age estimates of soil horizons have been published previously.[9,15] One of the most useful applications of soil morphology in archaeologic site interpretation is that of distinguishing ‘‘natural’’ from ‘‘artificial’’ or ‘‘man-influenced’’ horizons. Some natural horizons—such as a spodic (Bh) with a dark-colored, organic-rich matrix—may appear as a buried surface or midden. Some albic E horizons could be interpreted as ash layers. Other characteristics that are related to soil genesis, such as redoximorphic features (i.e., mottling or gleying), result from water table fluctuations and often cause confusion in interpretation of color in archaeologic levels. Horizons with calcium carbonate filling (Bk or Ck) have sometimes been identified as plaster-filled.
LABORATORY Laboratory soil characterization for archaeologic interpretations is used to verify and supplement field morphology. Laboratory analysis without complete soil morphology is generally of minimal value for archaeologic interpretation. Complete sampling of all soil horizons, columns, or archaeologic levels is also important to realize the full benefit of the additional cost and labor of soil analysis. Those laboratory analyses that are frequently applied in pedoarchaeology are organic carbon,[16] particle size distribution,[17] and elemental composition.[18] Other soil analysis may include pH, electrical conductivity, mineralogy, free iron, scanning electron microscopy (SEM), energy dispersive x-ray (EDAX), calcium carbonate, and micromorphology. The micromorphologic studies by Goldberg[19] and Macphail and Goldberg [20] have been especially useful in interpreting site stratigraphy and pedologic and geologic events.
FUTURE In the past few decades, pedologists have grown increasingly interested in work on archaeologic sites, and it is likely this trend will continue well into the future. Although we aid archaeologists in understanding the soils and pedologic features they carefully excavate, we have learned a great deal about weathering
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rates, horizon formation, and landscape development by teamwork with archaeologists and geologists. The use of additional techniques or applications by geoarchaeologists, such as x-ray diffraction (XRD), SEM, EDX, electrical resistivity, ground-penetrating radar, magnetic susceptibility, and micromorphology, will improve soil interpretation work in the future. Despite advances in analytical tools, the key to archaeologic site interpretation still remains the accurate, complete soil morphologic descriptions.
REFERENCES 1. Nikiforoff, C.C. Introduction to paleopedology. Am. J. Sci. 1943, 41, 194–200. 2. Dietz, E.F. Phosphorus accumulation in soil of an Indian habitation site. Am. Antiquity 1957, 22, 405–409. 3. Cook, S.F.; Heizer, R.F. Studies on the chemical analysis of archaeological sites. Univ. Calif. Pub. Anthropol. 1965, 2. 4. Sokoloff, V.P.; Carter, G.F. Time and trace metals in archaeological sites. Science 1952, 116, 1–5. 5. Cromwall, I.W. Soils for the Archeologist; Phoenix House Ltd.: London, 1958. 6. Olson, G.W. Soils and the Environment: A Guide to Soil Surveys and Their Application; Chapman and Hall: New York, 1981. 7. Foss, J.E. Paleosols of pompeii and oplontis. In Stvdia Pompeiana and Classics; Curtis, R.L., Ed.; Orpheus Pub. Inc.: 1988; 127–144. 8. Soils in archaeology; Holliday, V.T., Ed.; Smithsonian Institution Press: Washington, 1992. 9. Scudder, S.J.; Foss, J.E.; Collins, M.E. Soil science and archaeology. Advances in Agronomy 1996, 57, 1–76. 10. Collins, M.E., Carter, B.J., Gladfelter, B.G., Southard, R.J., Eds.; Pedological perspectives in archaeological research. Soil Sci. Soc. Am. Special Pub.; 1995; Vol. 44, 157 pp. 11. Foss, J.E., Timpson, M.E., Morris, M.W., Eds.; Proceedings of the First International Conference on Pedo-Archaeology. Univ. of Tennessee, Agr. Exp. Sta., Special Pub. 1993; Vol. 93–03, 210 pp. 12. Goodyear, A.C., Foss, J.E., Sassaman, K.E., Eds.; Proceedings of the Second International Conference on Pedo-Archaeology. South Carolina Institute of Archaeology and Anthropology, Univ. of South Carolina, Anthro. Studies. 1994; Vol. 10, 157 pp. 13. Foss, J.E.; Lewis, R.J.; Timpson, M.E.; Morris, M.W.; Ammons, J.T. Pedologic approaches to archaeological sites of contrasting environments and ages. Proceedings of the First International Conference on PedoArchaeology; Foss, J.E., Timpson, M.E., Morris, M.W., Eds.; Univ. of Tenn.; Agr. Exp. Sta. Spec. Pub., 1992; Vol. 93–03, 19–22. 14. Jenny, H. Factors of Soil Formation; McGraw-Hill: New York, 1941. 15. Foss, J.E.; Lewis, R.J.; Timpson, M.E. Soils in alluvial sequences: some archaeological implications.
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In Pedological Perspectives in Archaeological Research; Collins, M.E., Carter, B.J., Gladfelter, B.G., Southard, R.J., Eds.; Soil Sci. Soc. Am. Special Pub., 1995; Vol. 44, 1–14. 16. Stein, J.K. Organic matter in archaeological contexts. In Soils in Archaeology; Holliday, V.T., Ed.; Smithsonian Institute Press, 1992; 193–216. 17. Timpson, M.E.; Foss, J.E. The use of particle-size analysis as a tool in pedological investigations of archaeological sites. Proceedings of the First International Conference on Pedo-Archaeology; Collins, M.E., Carter, B.J., Gladfelter, B.G., Southard, R.J., Eds.; Univ. of Tenn. Agr. Exp. Sta. Spec. Pub., 1992; Vol. 93–03, 69–80.
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Archaeology and Soil
18. Schuldenrein, J. Geochemistry, phosphate fractionation, and the detection of activity areas at prehistoric North American sites. In Pedologic Perspectives in Archaeological Research; Collins, M.E., Ed.; Soil Sci. Soc. Am. Special Pub., 1995; Vol. 44, 107–132. 19. Goldberg, P. Micromorphology, soils, and archaeological Sites. In Soils in Archaeology; Holliday, V.T., Ed.; Smithsonian Institution Press: Washington, DC, 1992; 45–167. 20. Macphail, R; Goldberg, P. Recent advances in micromorphological interpretation of soils and sediments from Archaeological sites. In Archaeological Sediments and Soils; Barham, A.J., Macphail, R.I., Eds.; Institute of Archaeology, University College: London, 1995.
Arid Soils H. Curtis Monger New Mexico State University, Las Cruces, New Mexico, U.S.A.
INTRODUCTION Scarcity of rain is the dominant characteristic of arid soils. While age, parent material, carbonate, and salt content may vary from arid soil to arid soil, dryness is common to all. Of the total ice-free land area on Earth (130,797,000 km2), about 22% or 28,703,000 km2 is occupied by soils with aridic moisture regimes.[1] Although arid (L. aridus, dry) signifies lack of moisture, technical definitions of arid vary. In some cases, the arid–semiarid boundary is placed at 25 cm (10 in.) of annual rainfall.[2] In other systems, such as the Ko¨ppen–Geiger–Pohl and Meigs systems, the arid (desert)–semiarid (steppe) boundary is based on a combination of rainfall and temperature.[3,4] Still other systems, such as those by Strahler and Soil Survey Staff, use soil moisture to define arid zones because the availability of moisture to plants is more important than annual precipitation itself.[4,5] In all cases, however, rainfall is insufficient to maintain perennial streams. Soils in these regions are unique because relatively little water percolates deep enough to reach groundwater. As a result, carbonates, gypsum, and more soluble salts acumulate in the profiles of many arid soils.
ARID SOILS OF RIVER FLOODPLAINS Floodplain soils along rivers that flow through arid climates were sites of several ancient and eminent civilizations. Sumerian (ca. 3600 B.C.) and later Babylonian (ca. 2000 B.C.) civilizations grew into centers of trade and government as a result of irrigated agriculture on the Tigris and Euphrates River floodplains.[6] Likewise, soils and irrigated agriculture along the Nile of ancient Egypt, the Indus of ancient India, and the Hoang-Ho (Yellow River) of ancient China made it possible for civilizations to create notable schools, calendars, armies, mathematics, medicine, literature, philosophy, science, and art. In the western hemisphere as well, Hohokam, Aztec, and Inca societies emerged in arid and semiarid environments.[7] These civilizations existed because floodplain soils are well suited for irrigated agriculture if groundwater tables are sufficiently deep and salts do not accumulate. In the case of the Nile prior to dam construction, the river would rise and spill over its banks, flood the Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120015640 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
adjacent plain, deposit sediment, and leach salts.[7] In the case of the Tigris and Euphrates, however, drainage canals were needed to carry away leached salts, and with their demise soils became saline.
ARID SOILS ON UPLANDS Most soils in arid regions are not on floodplains, but occur in vast upland areas composed of three major landforms: mountains, piedmont slopes, and basin floors.[8] These major landforms, in turn, are composed of smaller, component landforms. Typically, soil boundaries correspond to component landforms. In mountains, for example, soil boundaries match the boundaries of colluvial wedges, valley fills, and pediments.[9] On piedmont slopes, soil boundaries parallel the boundaries of alluvial fans, ballenas, and fan skirts. On basin floors, which characteristically have little topographic relief, soil boundaries generally follow landforms produced by wind, such as deflational blowouts, dunes, and eolian plains, or landforms produced by pluvial lakes, such as lake plains, playas, and beach plains. Of the five soil-forming factors (climate, time, biota, topography, and parent material), climate is the defining factor of arid soils, although time is an important factor as well. The impact of time on arid soils is revealed by carbonate and clay accumulations in soils of progressively older geomorphic surfaces (Fig. 1). Carbonate in nongravelly soils, for example, progresses from carbonate filaments in middle Holocene soils to carbonate nodules in late Pleistocene soils to carbonate-indurated horizons in middle Pleistocene soils.[10] Clay likewise accumulates with time to form argillic horizons. However, the correlation of clay accumulation with time is less robust than carbonate accumulation with time because many ancient soils that have calcretes do not have argillic horizons.[11] This indicates that argillic horizons are more vulnerable to obliteration by erosion and bioturbation than calcic or petrocalcic horizons. Arid soils are not only unique because carbonate, gypsum, and soluble salt accumulate, but also because many have vesicular A-horizons covered by desert pavement[12] or microbiotic crust.[13] In addition, inadequate water and nitrogen suppress biomass 131
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Arid Soils
Fig. 1 Desert piedmont slope rising to a mountain chain in southern New Mexico. Progressively older geomorphic surfaces with progressively greater soil development are typical features of piedmont slopes. The younger soil on the right (about 3000 yr old) has a small amount of carbonate (white zone in profile). The older soil to the left (25,000–150,000 yr old) has substantially more carbonate. In addition, the older soil has an argillic horizon overlying the carbonate horizon.
production on arid soils to about one-tenth the biomass of temperate forest soils.[14] Nevertheless, soil animals such as rodents, ants, and termites are common. Ants, for example, can transfer 80 g=m2 of desert soil to the land surface per year, which is as much as ants transfer in more mesic environments.[15]
TYPES OF ARID SOILS The main criterion for the classification of arid soils is soil dryness, or the aridic (torric) moisture regime, which is defined as soils too dry for agricultural crops unless irrigated.[16] Further taxonomic subdivisions are based on diagnostic horizons. In contrast to the notion that arid soils are poorly developed, as written in some soil science books, many arid soils are strongly developed with a variety of diagnostic subsurface horizons.[17] These horizons include the argillic, natric,
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salic, gypsic, petrogypsic, calcic, and petrocalcic horizons, and the duripan.[5] Diagnostic surface horizons include the ochric epipedon with minor occurrences of the mollic and anthropic epidons. Arid soils that have diagnostic subsurface horizons are generally classified as Aridisols. These include many of the older soils on piedmont slopes, basin floors, mountain uplands. Various types of Aridisols occur on the landscape because of lateral changes in particle size, truncation of diagnostic horizons, degradation of diagnostic horizons, moisture heterogeneity across the landscape, and age differences, which can range from Historical to Pliocene within small geographical areas.[9,18] Arid soils that lack diagnostic subsurface horizons are generally classified as Entisols, which fall into the azonal concept of Sibirtsev.[19] These include many of the younger soils on floodplains, dunes, and erosional surfaces. In Soil Taxonomy, floodplain soils are mainly
Arid Soils
classified as Fluvents or, more specifically, Torrifluvents.[5] Arid soils associated with dunes are commonly Torripsamments and those associated with erosional surfaces are commonly Torriorthents. and Entisols Aridisols (14,942,000 km2) 2 (12,682,000 km ) are the dominant soil types in arid regions, although other soil types include Vertisols (889,000 km2) and Oxisols (31,000 km2) and very minor amounts of Mollisols, Andisols, Histosols, and Spodosols.[1] Arid soils grade into semiarid soils across three climatic transects: laterally into wetter regions, upslope into wetter climates at higher elevations, or downslope into run-in areas with wetter microclimates. Taxonomically, changes in soil types from dry region aridic to wetter region ustic or xeric moisture regimes are expressed at the Suborder and Great Group level (Fig. 2). Linked to this climatic transition is a progressive change in vegetation—desert shrublands give way to grasslands that in turn give way to wood-lands. Also across this transition, soils have progressively deeper carbonate horizons. In the Chihuahuan Desert, for instance, carbonate zones are 50 cm deep at 230 mm of annual rainfall and 100 cm deep at 320 mm of annual rainfall.[20] Likewise, gypsum zones progressively deepen from about 50 cm depth at 150 mm of annual rainfall to about 100 cm depth at 250 mm annual rainfall.[21] Accompanying an increase in rainfall is an increase in soil organic matter. Although the amount of organic matter depends on the clay content, organic matter ordinarily increases from less than 0.5% in A-horizons of arid shrubland soils to 2–5% in semiarid and subhumid grassland soils.[22]
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ECOLOGICAL SIGNIFICANCE Biodiversity in arid regions is linked to habitat diversity. Habitat diversity, in turn, is created by various microclimates caused by topographic factors and soil properties.[23] Thus, soils help mold and are molded by ecosystems. In many arid regions, such as the southwestern United States, soils have been impacted by ecosystem changes of the Holocene and late Pleistocene when wetter climates alternated with drier climates.[24,25,26,27] According to this model, landscape stability was greater during wetter climates because denser vegetative cover reduced erosion. With reduced erosion, soil formation occurred. In contrast, instability was greater during drier climates because sparse vegetative cover gave rise to more bare ground and increased erosion. With increased erosion, soil formation was inhibited. This oscillation between stability and instability is recorded as stacked sequences of buried paleosols in depositional environments and as stepped sequences of fan-terraces in areas that grade to fluctuating river base-levels. Globally, arid soils affect atmospheric dust, rain chemistry, ocean fertilization, albedo, denitrification, and the carbon cycle as both sinks and sources of CO2.[28,29] Carbonate–carbon, for instance, is the second largest terrestrial carbon pool, totaling approximately 50–60 Pg C in the dryland zones of the U.S.[30] and approximately 750–950 Pg C in the dryland zones of the world.[31] Humans have lived on arid soils for millennia. In fact, the oldest known hominid tools are in arid East Africa and date back 2.5 million yr.[32] Today arid
Fig. 2 Illustration of Soil Taxonomy Suborders and Great Groups that have aridic moisture regimes (shaded) and their moister counterparts that have ustic and xeric moisture regimes. (From Ref.[5].)
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soils are important to humans for livestock grazing, irrigated agriculture, and urban development. In many arid regions of the world, human land use has resulted in desertification and diminishing groundwater supplies, both of which are increasingly important social and scientific issues as human population increases. ACKNOWLEDGMENTS Grateful acknowledgment is made to Haiyang Xing and Marco Inzunza for making the figures and Rebecca Kraimer for reviewing the manuscript. REFERENCES 1. Wilding, L.P. Introduction: general characteristics of soil orders and global distributions. In Handbook of Soil Science; Sumner, M.E., Ed.; CRC Press: Boca Raton, FL, 2000; E175–E182. 2. Bull, W.B. Geomorphic Responses to Climatic Change; Oxford University Press: New York, 1991; 326 pp. 3. Dick-Peddie, W.A. Semiarid and arid lands: a worldwide scope. In Semiarid Lands and Deserts; Skuji}s, J., Ed.; Marcel Dekker: New York, 1991; 3–32. 4. Strahler, A.N.; Strahler, A.H. Modern Physical Geography, 3rd Ed.; Wiley: New York, 1987; 544 pp. 5. Soil survey staff. Soil Taxonomy—A Basic System of Soil Classification for Making and Interpreting Soil Surveys, 2nd Ed.; USDA Agriculture Handbook Number 436; U.S. Govt. Printing Office: Washington, DC, 1999. 6. Durant, W. Our Oriental Heritage; Simon and Schuster: New York, 1935; 1049 pp. 7. Dregne, H.E. Soils of Arid Regions; Elsevier: Amsterdam, 1976; 237 pp. 8. Peterson, F.F. Landforms of the Basin and Range Province Defined for Soil Survey; Nevada Agricultural Experiment Station, Tech. Bull. 28, Univ. of Nevada: Reno, 1981; 52 pp. 9. Gile, L.H.; Hawley, J.W.; Grossman, R.B. Soils and Geomorphology in the Basin and Range Area of Southern New Mexico—Guidebook to the Desert Project; New Mexico Bureau of Mines and Mineral Resources, Memoir 39, Socorro: New Mexico, 1981; 222 pp. 10. Gile, L.H.; Peterson, F.F.; Grossman, R.B. Morphology and genetic sequences of carbonate accumulation in desert soils. Soil Sci. 1966, 101, 347–360. 11. Gile, L.H. Eolian and associated pedogenic features of the jornada basin floor, southern new mexico. Soil Sci. Soc. Am. J. 1999, 63, 151–163. 12. McFadden, L.D.; Wells, S.G.; Jercinovich, M.J. Influences of eolian and pedogenic processes on the origin and evolution of desert pavements. Geology. 1987, 15, 504–508. 13. Kidron, G.J.; Yaalon, D.H.; Vonshak, A. Two causes for runoff initiation on microbiotic crusts: hydrophobia and pore clogging. Soil Sci. 1999, 164, 18–27. 14. Ludwig, J.A. Primary productivity in arid lands: myths and realities. J. Arid Environ. 1987, 13, 1–7.
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Arid Soils
15. Whitford, W.G.; Schaefer, D.; Wisdom, W. Soil movement by desert ants. The Southwestern Naturalist. 1986, 31, 273–274. 16. Smith, G.D. The Guy Smith Interviews: Rationale for Concepts in Soil Taxonomy; Soil Management Support Service Monograph No. 11; U.S. Government Printing Office: Washington, 1986. 17. Ahrens, R.J.; Eswaran, H. The international committee on aridisols: deliberations and rationale. Soil Surv. Horizons. 2000, 41, 110–117. 18. Gile, L.H. Causes of soil boundaries in an arid region; I. age and parent materials. Soil Sci. Soc. Am. Proc. 1975, 39, 316–323. 19. Sibirtsev, N.M. Selected Works, Soil Science; Issued in Translation by the Israel Program for Scientific Translation: Jerusalem, 1966; Vol. 1, 354 pp. 20. Gile, L.H. Holocene soils and soil-geomorphic relations in a semi-arid region of southern new mexico. Quatern. Res. 1977, 7, 112–132. 21. Cooke, R.; Warren, A.; Goudie, A. Desert Geomorphology; UCL Press: London, 1993; 526 pp. 22. Birkeland, P.W. Soils and Geomorphology, 3rd Ed.; Oxford University Press: New York, 1999; 430 pp. 23. McAuliffe, J.R. Landscape evolution, soil formation, and ecological patterns and processes in sonoran desert bajadas. Ecol. Monogr. 1994, 64, 111–148. 24. Ruhe, R.V. Age of the rio grande valley in southern New Mexico. J. Geol. 1962, 70, 151–167. 25. Gile, L.H.; Hawley, J.W. Periodic sedimentation and soil formation on an alluvial-piedmont in southern New Mexico. Soil Sci. Soc. Am. Proc. 1966, 30, 261–268. 26. Monger, H.C.; Cole, D.R.; Gish, J.W.; Giordano, T.H. Stable carbon and oxygen isotopes in quaternary soil carbonates as indicators of ecogeomorphic changes in the northern chihuahuan desert, USA. Geoderma 1998, 137–172. 27. Buck, B.J.; Monger, H.C. Stable isotopes and soilgeomorphology as indicators of holocene climate change, northern chihuahuan desert. J. Arid Environ. 1999, 43, 357–373. 28. Schlesinger, W.H.; Reynolds, J.F.; Cunningham, G.L.; Huenneke, L.F.; Jarrell, W.M.; Virginia, R.A.; Whitford, W.G. Biological feedbacks in global desertification. Science 1990, 247, 1043–1048. 29. Schlesinger, W.H. Biogeochemistry: An Analysis of Global Change, 2nd Ed.; Academic Press: New York, 1997. 30. Monger, H.C.; Martinez-Rios, J.J. Inorganic carbon sequestration in grazing lands. In The Potential of U.S. Grazing Lands to Sequester Carbon and Mitigate the Greenhouse Effect; Follette, R.F., Kimble, J.M., Lal, R., Eds.; CRC Press: Boca Raton, FL, 2001; 87–118. 31. Eswaran, H.; Reich, P.F.; Kimble, J.M.; Beiroth, F.H.; Radmanabhan, E.; Moncharoen, P. Global carbon sinks. In Global Climate Change and Pedogenic Carbonates; Lal, R., Ed.; CRC Press: Boca Raton, FL, 2000; 15–26. 32. Ambrose, S.H. Paleolithic technology and human evolution. Science 2001, 291, 1748–1753.
Atterberg Limits Thomas Baumgartl Institute for Plant Nutrition and Soil Science, Kiel, Germany
INTRODUCTION Soil is exposed to different states of stability depending on the amount of water that it contains. This characteristic is described as consistency (refer to entry on soil consistency and plasticity) and specifies the state of a remolded and cohesive soil in the range from the liquid (when wet) to plastic and finally solid (when dry) state. Different soils contain a specific amount of water at these different states of stability. In 1911, the Swedish soil physicist Atterberg developed a classification system and method with which these states of consistency could be determined. The method is based on the determination of the water content [calculated as: (mass of water)=(dry mass of soil)] at distinct transitions between different states of consistency of soil. These transitions are defined as liquid limit, plastic limit and shrinkage limit, and are generally referred to as Atterberg limits. The values for these limits are dependent on various soil parameters, e.g., particle size, specific surface area of the particles which is able to take up water, and hence its particle size distribution. These limits are used to derive indices, e.g., index of plasticity and index of consistency, and are often used for the mechanical characterization of soils.
DEFINITION OF LIMITS AND THEIR DETERMINATION Liquid Limit (Upper Plastic Limit) wL The liquid limit describes the transition from a viscous liquid to a plastic state. Soils with a water content at the liquid limit barely flow under an applied force. The associated capillary forces of the water menisci in the unsaturated pore system are equivalent to pF 0.5 (0.3 kPa matric potential).[1] The liquid limit is determined by a method and device developed by Casagrande. The principle is to find the water content (kg=kg) at which a soil sample starts to liquify under a small applied stress. In practice a groove is cut into soil samples with different water contents. These soil samples are then exposed to a small standardized force by repeatedly dropping the Casagrande cup over a distance of 10 mm until the groove is close to ca. 10 mm. A semilogarithmic plot of the number of Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001729 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
blows as a function of water content will result in a straight line. The liquid limit is defined as the water content at 25 blows (Fig. 1). Plastic Limit (Lower Plastic Limit) wP The plastic limit determines the transition from a plastic (cohesive) to a semirigid or brittle state. Under an applied force cracking will occur. In sandy soils the plastic limit often cannot be determined. The matric potential at the plastic limit is the main cohesive stress and ranges between 63 and 200 kPa (pF 2.8–3.3).[1] The plastic limit is determined by forming a moist ball from 2 to 3 g of soil, which is then rolled on a piece of frosted glass to a rod of thickness ca. 3 mm. The remolding and rolling is repeated until the 3 mm rod starts to break up into pieces of 10–20 mm. The gravimetric water content (kg=kg) at this point gives the plastic limit. Shrinkage Limit wS Cohesive and remolded soils reduce their soil volume with the loss of water due to capillary forces. If in a drying process the reduction of the total soil volume equals the volume of water loss, then the soil shows normal shrinkage. Below a certain water content, the further shrinkage of the soil volume is restricted due to a high number of particle contact points and high effective stresses. This restricted shrinkage pattern is called residual shrinkage (Fig. 2). The transition from normal to residual shrinkage defines the shrinkage limit. The shrinkage limit is often calculated by wS ¼ 0:65 wP Index of Plasticity IP The index of plasticity is the amount of water between plastic and liquid limit and is calculated by IP ¼ wL wP It describes the sensitivity in the mechanical behavior of a soil towards changes in water content. However, it does not explain mechanical stability as hydraulic parameters are not included which are necessary as water flow becomes important when stresses are applied on a 135
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Atterberg Limits
The water content w as such provides no information about the consistency of soils. The same water content in a sandy soil may reflect a liquid state, where as in a clay soil the behavior may be brittle. The index of consistency normalizes the water contents and characterizes whether the soil is close to the plastic limit ðmax IC ¼ 1Þ or the liquid limit ðmin IC ¼ 0Þ.
Number of blows
100
Index of Shrinkage ISch
25
The difference between the plastic limit and the shrinkage limit results in the index of shrinkage: ISch ¼ wP wS 10 0.2
0.3
0.4
0.5
Water content
wL
Soils with water contents within this range are most suitable for cultivation (see Fig. 2). Table 1 summarizes some general values for the Atterberg limits and indices.[8]
Fig. 1 Determination of the liquid limit.
soil sample. Values for the index may range from 0 (no plastic behavior) for sandy material to 1 (100%) for clay. Index of Consistency IC The index of consistency is determined as the ratio of the difference between the liquid limit and actual water content and the index of plasticity: IC ¼
wL w wL w ¼ wL wP IP
Specific volume [cm3/g soil]
FACTORS INFLUENCING THE ATTERBERG LIMITS Many mechanical processes are linked to hydrological properties of soils. Therefore, values of the limits and indices are influenced by factors which are generally important for the water retention curve, e.g., the capacity of swelling and shrinkage, clay content, type of clay minerals and organic matter. Generally, the values of the limits and indices increase with their clay content. As the liquid limit increases in comparison to the plastic limit, the index of plasticity also increases. The swelling and shrinkage intensity is dependent not only on the amount but also on the type of clay mineral. Skempton introduced a factor described as the activity of clay:[2,9] A ¼
Normal shrinkage
IP : % clay content
Shrinkage
The values of A can be classified as: 1) A > 1.25: active soil with high capacity of swelling and shrinking [Ca-montmorillonite (A 1.5), Na-montmorillonite Table 1 Consistency limits (g water=g soil) for different soil textures
Residual shrinkage
Texture ISch
wS
Ip
wP wL Water content [g/g]
Fig. 2 Shrinkage behavior with change in water content; relations to Atterberg limits wS, wP, wL and Atterberg indices. (From Ref.[9].)
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Sand
Silt
Clay
Liquid limit
0.15–0.20
0.30–0.40
0.40–1.50
Plastic limit
0
0.20–0.25
0.25–0.5
Index of plasticity
0
0.10–0.15
0.10–1.00
0.12–0.18
0.14–0.25
0.08–0.25
Consistency limits
Shrinkage limit (From Ref.[8].)
Atterberg Limits
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Table 2 Mechanical properties of soils and Atterberg limits Index of consistency Symbol
0
0.25
1
1.3
wP
wS
Index of plasticity Slurry
Unconfined compression strength (kPa) Cultivation (pos., þ; neg., )
0.75
wL
Index Description
0.5
Index of shrinkage
Very soft
Soft
Deformable
Stiff
Medium hard
Hard
400
þ
(From Refs.[2,9].)
(A 7.5), smectite, salt influenced clays]); 2) 0.75 < A < 1.25: normal soils (illite); 3) A < 0.75: inactive clay with only little swelling–shrinking activity (kaolinite). Organic matter increases both the plastic and liquid limits, but does not have a big effect on the index of plasticity. Organic substances in a soil matrix seem therefore to increase the surface hydration. Once this pool for water uptake is saturated, the soil shows the same mechanical behavior towards changes in water content as when organic matter is absent, only at a higher level of water content. Thus, the index of consistency is higher.[1] With the exception of organic matter and clays, the amount and type of exchangeable cations have a significant effect on the value of the limits.[3,5,12] Nasaturated soils reduce the liquid limit, but increase the shrinkage limit. Soils therefore have the tendency to show crust formation at an earlier stage and will slake at lower water contents.[1,8]
and 1. Drier soils increase the energy input needed for cultivation, which can be a serious problem for clay-rich soils as plowing can become difficult. In the case of lower than optimal plasticity indices, the soil structure can be destroyed easily when the soil is kneaded by trafficking resulting in ecological problems. As a result, the hydraulic conductivity and gas flow as well as nutrient uptake of plants can be reduced. Hence, cultivation at index of consistency smaller than 0.75 can have a serious effect on plant growth and soil biological activity. Although the values of the limits and indices are not independent values, they can be related to each other (e.g., IP and wL). Classifications with respect to particle size distribution, geological origin of material, and suitability under soil mechanical point of view can be derived thereafter. With the ratio of liquid limit and index of plasticity a linear relationship was found by Casagrande and described as A-line,[13] following the equation: IP ¼ 0:73ðwL 0:2Þ
APPLICATION
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70 increase of plasticity
60
e
lin
A-
Index of plasticity
Soil charcteristics are inherent in the values of the Atterberg limits. Therefore, Atterberg limits are correlated with soil properties. For specific soils, investigations have been carried out which correlate the total particle surface with the plastic limit.[4,6] Soil strength can be defined by its compressibility and compressibility is correlated to the Atterberg limits.[11] As soil strength is influenced to a great extent by the energy status of the capillary water, Atterberg limits reflect the soil water potential and show the dependency on texture and the water retention curve.[10] At a broader scale, the Atterberg limits can be used for the evaluation of the trafficability and cultivation of soils. Table 2 lists the limits and derived mechanical properties and qualities of soil substrates. From this classification (Table 2), it is evident that an optimal range of water contents for agricultural use can be determined. This range is present when the soil is stiff and has a compression strength of >100 kPa and an index of consistency between 0.75
50 40 30
ic
ic
or
d
in
ills
c
10
cohesionless soils
g
i an
or
in
cl
an
n ga
20
s
ay
ys
a cl
g or
an
s
increase of compactiblity
0 0
20 30
40 50 60
80
100
Liquid limit Fig. 3 Classification of soils according to Atterberg limits and Casagrande A-line.
138
Atterberg Limits
Table 3 Mechanical parameters (angle of internal friction, cohesion) dependent on texture and index of plasticity IP
Angle of internal friction }0 ( )
Cohesion (kPa)
Clay of high plasticity: wL > 0.5
0.50–0.75 0.75–1.00 1.00–1.30
17.5 17.5 17.5
0 10 25
Clay and silt of medium plasticity: 0.35 < wL < 0.5
0.50–0.75 0.75–1.00 1.00–1.30
22.5 22.5 22.5
0 5 10
Clay and silt of low plasticity: wL < 0.35
0.50–0.75 0.75–1.00 1.00–1.30
27.5 27.5 27.5
0 2 5
Texture
(Adapted from Ref.[9].)
It distinguishes soil with content of organic matter of selenate. For the anions, the greater the chemical attraction for the surface, the more marked the continuing reaction. The continuing reaction is caused by diffusion of adsorbed
BEHAVIOR OF SOME IONS Before considering the ions in detail, note that selenate, sulfate, phosphate, selenite, and arsenate all form bidentate, inner-sphere complexes with the surface. That is, two of the oxygen atoms provide direct chemical links to the surface atoms. When a reactant forms a bidentate link to the surface, it is appropriate to refer to the divalent ion in solution.[1] Similarly, in the case of a monodentate link, as with borate, it is appropriate to refer to the monovalent ion. Boric acid is fairly weak, with pH at about 9. Therefore, in the normal range of soil pH, the proportion of monovalent borate ion increases 10-fold for each unit increase in pH. The effects of pH on the charge and potential and the effects on acid dissociation therefore oppose each other: the increasingly negative electric potential favors decreased desorption; the increasing dissociation favors increased adsorption. Because the ion is monovalent, the effects of surface charge are not quite large enough to exceed the effects of the increasing value of the dissociation term. Thus, sorption increases with increasing pH. Selenious acid is a diprotic acid with pK1 at 2.7 and pK2 at 8.5 in very dilute solution. The main species present in the range of soil pH values are HSeO3 and SeO32, with the divalent ion increasing with increasing pH. However, because the relevant ion is divalent, the effects of the increasingly negative
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Fig. 3 The effect of period of reaction at 25 C for selenite and zinc on the relationship between solution concentration and amount of sorption. The lines were obtained by fitting the model described in the text to the data. (From Ref.[1].)
Chemisorption
ions into the absorbing particle. This is a slow process but can be accelerated by raising the temperature. Consequently, increased temperature increases sorption and/or decreases solution concentration.
DESORPTION The more marked the continuing reaction, the more deeply buried the ion becomes. Although desorption
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221
curves do not seem to follow the same track as sorption curves, they can be fully predicted if the continuing reaction is taken into consideration.
REFERENCE 1. Barrow, N.J. The four laws of soil chemistry: the leeper lecture 1998. Aust. J. Soil Res. 1999, 37, 787–829.
Chlorine Uzi Kafkafi The Hebrew University of Jerusalem, Rehovot, Israel
Guohua Xu College of Resources and Environmental Sciences, Nanjing Agricultural University, Nanjing, China
INTRODUCTION Chlorine is found in nature in the form of negatively charged (Cl), highly water-soluble anion. Most of the world’s Cl is found either in oceans or in salt deposits left by evaporation of old inland seas, which are now found in deep quarries. Field and glasshouse studies in the mid-1800s to the early 1900s have shown that the influence of Cl on plant growth varies with the plant variety.[1] Lipman[2] demonstrated the beneficial effect of Cl on buckwheat (Triticum asetivum L.) growth. Arnon and Whatley[3] suggested that Cl is an essential cofactor in the O2 evolution during photosynthesis. The first complete definition of Cl, as a plant essential micronutrient was described by Broyer et al.[4] The function of Cl in crop yield has been largely neglected,[5] as it becomes a limiting factor for plant growth only in areas of high precipitation far from the sea. The negative effects of high Cl concentrations in soil and irrigation water on crop production are observed in coastal, arid and semi-arid areas, where freshwater sources are often scarce and the available groundwater is saline. The dependence of modern agriculture on irrigation and fertilization causes more concern on excess of Cl rather than on its deficiency.[6]
CHLORIDE IN SOIL The concentrations of Cl in natural sources are listed in Table 1. The Cl content in the soil is not an intrinsic property of the soil but rather a result of soil management, rainfall and evaporation, and irrigation and fertilization. The Cl concentration in rainwater ranges from about 20–50 g=m3 close to seashore to 2–6 g=m3 in inner continental areas.[5,7] The annual amount of Cl deposition on land ranges from 17–175 kg=ha. Mid-continental areas such as the Great Plains of North America receive 6.0–7.0
Asteraceae
Lettuce
Lactuca sativa L.
Leaves
>0.14
2.8–19.8
>15.0
References [21,23] [19]
>23.0
[24]
Chenopodiaceae
Spinach
Spinacia oleracea L.
Shoot
>0.13
[25]
Chenopodiaceae
Sugarbeet
Beta vulgaris L.
Leaves
0.71–1.78
[26]
Chenopodiaceae
Sugarbeet
Beta vulgaris L.
Petioles
7.1–7.2
>50.8
[6,26]
Fabaceae
Alfalfa
Medicago sativa L.
Shoot
0.65
0.9–2.7
6.1
[27,28]
Fabaceae
Peanut
Arachis hypogaea L.
Shoot
4.6
0.3–1.5
16.7–24.3
Fabaceae
Red clover
Trifolium pratense L.
Shoot
Fabaceae
Soybean
Glycine max L. Merr.
Leaves
Fabaceae
Subterranean clover
Trifolium subterraneum L.
Shoot
>1.0
Gramineae
Barley
Hordeum vulgare L.
Heading shoot
1.2–4.0
Gramineae
Corn
Zea mays L.
Ear leaves
Gramineae
Corn
Zea mays L.
Shoots
0.05–0.11
Gramineae
Rice
Oryza sativa L.
Shoot
5.3
[29,35]
Rutaceae
Citrus
Citrus sp. L.
Leaves
2.0
4.0–7.0
Solanaceae
Potato
Solanum tuberosum L.
Mature shoot
4.0 1.1–10.0
[5,9] >32.7
[33] [24]
>7.0–8.0
[34]
5.1–10.0
>13.6
[6]
1.5
3.7–4.7
>7.0
[5,29]
1.2–4.0
>4.0
[5,9]
1.5–4.0
7.0
10.0–25.0
>25.0–33.1
[6]
>2.1
[28]
0.1
1.2–10.0 0.7–8.0
[28,35]
[20]
b
10–40 0.25
[20]
>10.0
[6,28]
30.0
[4,38]
10.0–11.0
[6,28] Chlorine
a
0.15–0.21
[29]
Chlorine
cells, and consequent stomata opening. The relative contribution of Cl and malate may vary among species, and depend on the availability of external Cl and plant growth environment.[17] In plant species such as onion (Allium cepa L.), which lack the functional chloroplasts for malate synthesis in the guard cells, Cl is essential for stomata functioning.[17,18] Members of the Palmaceae, such as coconut and oil palm, which might possess starch-containing chloroplasts in their guard cells, also require Cl for stomata function.[19]
INTERACTION OF CHLORIDE UPTAKE WITH THE UPTAKE OF OTHER NUTRIENTS Ammonium is taken up by plant as a cation, and therefore relatively more anions have to be taken up to maintain the electrical neutrality of the uptake process. Plants fertilized with NH4þ, usually contain higher Cl levels in the tissue than plants fertilized with NO3 or with both N sources, irrespective of the Cl concentration in the nutrient solution.[6] Thus, when Cl is present in the root medium, NH4þ uptake may increase the salt sensitivity of the plants. The antagonism between NO3 and Cl uptake has been well demonstrated in many crops.[6] When both Cl and NO3 anions are taken up by the root against their electrochemical gradient, Cl maintains its negative charge, while NO3 is metaboliszed and loose its negative charge. The accumulation of Cl reduces its further uptake since the Cl electrochemical potential gradient builds up during its accumulation in the cell.[20] Nitrate can prevent Cl toxicity of avocado at a concentration of up to 16 mM in the root medium.[20] On the other hand, Cl application may also be used as a strategy to decrease the NO3 content of leafy vegetables, as spinach (Spinacia oleracea L.), lettuce, and cabbage (Brassica oleracea L.), which are classified as NO3 accumulators.[6] Increasing concentrations of Cl in the root medium has generally no consistent effect on K concentrations in the plants. Potassium concentrations in the leaves of kiwifruit are significantly higher for vines receiving KCl than for vines receiving K2SO4 as the kiwifruit uses Cl rather than organic anions for charge balance, and thus maintains a high K uptake.[21]
CHLORIDE MANAGEMENT IN IRRIGATION AND FERTILIZATION Large amounts of Cl enter the field through irrigation. The amount of Cl added to a field with 500 mm of irrigation water containing only 200 g Cl=m3 is only 1000 kg=ha. This is four times more than the amount of Cl applied by fertilization with KCl at 500 kg=ha.
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The irrigation system influences the distribution of Cl salts in the soil. Irrigation with saline water is managed by an excess of irrigation to meet the leaching requirement for avoiding salt accumulation in the root zone.[22] The amount of water required to wash salts out of the root zone can be estimated from the electrical conductivity (EC) of the irrigation water and the mean EC of the saturated soil extract at which no crop yield reduction occurs under sprinkler or surface irrigation.[22] Fertilization with KNO3 under saline conditions might reduce the toxic effect of salinity of some woody plants even if it is associated with increased soil osmotic potential.[20] Under high salinity and Cl conditions, KNO3 or K2SO4 as K fertilizers are preferred due to their lower salt index and absence of Cl. Addition of adequate P can also be helpful in alleviating salt stress.[6]
CONCLUSIONS Chloride ion is essential for plant growth as a micronutrient. It is taken up by plants in large quantities when its concentration in the soil is elevated due to irrigation, fertilization, and evaporation of water from the soil surface. Cl deficiency was monitored in inland regions with ample rainfall. There is a wide range of Cl concentrations needed by plants, [from Cl-sensitive plants like avocado to tolerant plants like coconuts.] The main load of Cl is observed when irrigation with saline water is employed. The main Cl rich fertilizer is KCl that is normally applied without deleterious effects.
REFERENCES 1. Tottingham, W.E. A preliminary study of the influence of chlorides on the growth of certain agricultural plants. J. Am. Soc. Agron. 1919, 11, 1–32. 2. Lipman, C.B. Importance of silicon, aluminum, and chlorine for higher plants. Soil Sci. 1938, 45, 189–198. 3. Arnon, D.L.; Whatley, F.R. Is chloride a coenzyme of photosynthesis? Science 1949, 110, 554–556. 4. Broyer, T.C.; Carlton, A.B.; Johnson, C.M.; Stout, P.R. Chloride—a micronutrient element for higher plants. Plant Physiol. 1954, 29, 526–532. 5. Fixen, P.E. Crop responses to chloride. Adv. Agron. 1993, 50, 107–150. 6. Xu, G.H.; Magen, H.; Tarchitzky, J.; Kafkafi, U. Advances in chloride nutrition of plants. Adv. Agron. 2000, 68, 97–150. 7. Yaalon, D.H. The origin and accumulation of salts in groundwater and in soils in Israel. Bull. Res. Counc. Israel 1963, 11G, 105–131. 8. Wang, J.H.; Yu, T.R. Release of hydroxyl ions during specific adsorption of chloride by variable-charge soils. Z Pflanzenernahr Bodenk 1998, 161, 109–113.
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9. Engel, R.E.; Bruckner, P.L.; Mathre, D.E.; Brumfield, S.K.Z. A chloride deficient leaf spot syndrome of wheat. Soil Sci. Soc. Am. J. 1997, 61, 176–184. 10. Maas, E.V. Physiological responses to chloride. In Special Bulletin on Chloride and Crop Production, No. 2; Jackson, T.L., Ed.; Potash & Phosphate Institute: Georgia, 1996; 4–20. 11. Felle, H.H. The Hþ=Cl symporter in root-hair cells of Sinapsis alba. An electrophysiological study using ionselective microelectrodes. Plant Physiol. 1994, 106, 1131–1136. 12. Glass, A.D.M.; Siddiqi, M.Y. Nitrate inhibition of chloride influx in barley: implications for a proposed chloride homeostat. J. Exp. Bot. 1985, 36, 557–566. 13. Rognes, S.E. Anion regulation of lupin asparagine synthetase: chloride activation of the glutamine-utilizing reaction. Phytochemistry 1980, 19, 2287–2293. 14. Churchill, K.A.; Sze, H. Anion-sensitive, Hþ-pumping ATPase of Oat roots. Plant Physiol. 1984, 76, 490–497. 15. Hofinger, M.; Bottger, M. Identification by GC-MS of 4-chloroindolylacetic acid and its methyl ester in immature Vicia faba broad bean seeds. Phytochemistry 1979, 18, 653–654. 16. Flowers, T.J. Chloride as a nutrient and as an osmoticum. Adv. Plant Nutr. 1988, 3, 55–78. 17. Talbott, L.D.; Zeiger, E. Central roles for potassium and sucrose in guard-cell osmoregulation. Plant Physiol. 1996, 111, 1051–1057. 18. Schnabl, H.; Raschke, K. Potassium chloride as stomatal osmoticum in Allium cepa L. (onion), a species devoid of starch in guard cells. Plant Physiol. 1980, 65, 88–93. 19. von Uexkull, H.R. Chloride in the nutrition of coconut and oil palm. Trans. Int. Congr. Soil Sci. 1990, IV (14), 134–139. 20. Bar, Y.; Apelbaum, A.; Kafkafi, U.; Goren, R. Relationship between chloride and nitrate and its effect on growth and mineral composition of avocado and citrus plants. J. Plant Nutr. 1997, 20, 715–731. 21. Buwalda, J.G.; Smith, G.S. Influence of anions on the potassium status and productivity of kiwifruit (Actinidia deliciosa) vines. Plant Soil 1991, 133, 209–218. 22. Keller, J.; Bliesner, R.D. Trickle irrigation planning factor. In Sprinkler and Trickle Irrigation; Keller, J., Bliesner, L.R.D., Eds.; Van Nostrand Reinhold: New York, 1990; 453–477. 23. Prasad, M.; Burge, G.K.; Spiers, T.M.; Fietje, G. Chloride induced leaf breakdown in kiwifruit. J. Plant Nutr. 1993, 16, 999–1012.
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Chlorine
24. Johnson, C.M.; Stout, P.R.; Broyer, T.C.; Carlton, A.B. Comparative chloride requirements of different plant species. Plant Soil 1957, 8, 337–353. 25. Robinson, S.P.; Downton, W.J.S. K, Na and Cl content of isolated intact chloroplasts in relation to ionic compartmentation in leaves. Arch. Biochem. Biophys. 1984, 228, 197–206. 26. Ulrich, A.; Ohki, K. Chloride, bromine, and sodium as nutrients for sugar beet plants. Plant Physiol. 1956, 31, 171–181. 27. Ozanne, P.G.; Woolley, J.T.; Broyer, T.C. Chloride and bromine in the nutrition of higher plants. Aust. J. Biol. Sci. 1957, 10, 66–79. 28. Eaton, F.M. Chapter: Chlorine. In Diagnostic Criteria for Plants and Soils; Chapman, H.D., Ed.; University of California: Riverside, 1966; 98–135. 29. Wang, D.Q.; Guo, B.C.; Dong, X.Y. Toxicity effects of chloride on crops. Chin. J. Soil. Sci. 1989, 30, 258–261. 30. Whitehead, D.C. Chlorine deficiency in red clover grown in solution culture. J. Plant Nutr. 1985, 8, 193–198. 31. Parker, M.B.; Gaines, T.P.; Gascho, G.J. The chloride toxicity problem in soybean in Georgia. In Special Bulletin on Chloride and Crop Production, 2nd Ed.; Jackson, T.L., Ed.; Potash & Phosphate Institute: Atlanta, 1986; 100–108. 32. Yang, J.; Blanchar, R.W. Differentiating chloride susceptibility in soybean cultivars. Agron. J. 1993, 85, 880–885. 33. Parker, M.B.; Gaines, T.P.; Gascho, G.J. Chloride Effects on Corn. Commun. Soil Sci. Plant Anal. 1985, 16, 1319–1333. 34. Yin, M.J.; Sun, J.J.; Liu, C.S. Contents and distribution of chloride and effects of irrigation water of different chloride levels on crops. Soil Fert. 1989, 1, 3–7 (Chinese). 35. Robinson, J.B. Fruits, vines and nuts. In Plant Analysis—An Interpretation Manual; Reuter, D.J., Robinson, J.B., Eds.; Inkata Press: Sydney, 1986; 120–147. 36. Corbett, E.G.; Gausman, H.W. The interaction of chloride and sulfate in the nutrition of potato plants. Agron. J. 1960, 52, 94–96. 37. James, D.W.; Weaver, W.H.; Reeder, R.L. Chloride uptake by potatoes and the effects of potassium chloride, nitrogen and phosphorus fertilization. Soil Sci. 1970, 109, 48–53. 38. Kafkafi, U.; Valoras, N.; Letay, J. Chloride interaction with NO3 and phosphate nutrition in tomato. J. Plant Nutr. 1982, 5, 1369–1385.
Classification Systems: Australian and New Zealand Terry A. Isbell A. E. Hewitt Landcare Research, Lincoln, New Zealand
INTRODUCTION Although Australia and New Zealand are relatively close neighbors, both are independent island states and this probably accounts for some degree of isolation between the two countries. In terms of size, climate, geology, vegetation, and land forms, there are striking differences, and it is not surprising, that the New Zealand soil pattern is mostly very different from that of much of Australia. It also follows for these factors, and other national differences, that separate soil classification schemes have always been in use. It is widely accepted that classification is an essential part of any scientific discipline and is a necessary part of the language of science. No classification scheme can remain static; as new knowledge is gained, soil classifications need to be updated and improved. The history of national soil classifications in Australia[1,2] is a good example of how benefits are obtained from modifications in the light of new knowledge. This, in effect, largely explains why Australia has rightly had a succession of national classification schemes. It is also of interest to note that two of the still commonly used schemes—the Factual Key of Northcote[3] and the so-called Handbook of Australian Soils[4]—were a direct result of the decision to hold the Ninth International Congress of Soil Science in Adelaide, Australia, in 1968. This meeting served as a catalyst to increase rapidly the knowledge about Australian soils by means of a targeted approach to the mapping of the continent at a published scale of 1 : 2 million using the Factual Key.[3] This was achieved on time in spite of the size and soil diversity of the Australian continent. The Factual Key is a bifurcating, hierarchical scheme with five categorical levels. All classes are mutually exclusive, and the keying morphological attributes are determined in the field, including the pH and the presence of carbonate as determined by a simple field test. Most class names are descriptive, e.g., ‘‘Hard Pedal Mottled Red Duplex Soils.’’ The associated Handbook of Australian Soils[4] was a separate exercise to the soil mapping project and is a compendium of morphological and laboratory data of 94 soil profiles which were visited on the 1968 Congress field excursions, plus some extra representative soils (147) not visited in the field tours. The ‘‘Handbook’’ 230 Copyright © 2006 by Taylor & Francis
is not a formal classification but is an assemblage of ‘‘great soil groups’’ largely derived from Stephens.[5] This was more or less current at the time and was essentially based on the earlier United States Department of Agriculture schemes that were in vogue prior to the formal advent of the early Soil Taxonomy Approximations of the 1960s. Both the Factual Key and the Handbook are still widely used in Australia, the former mainly because of the Australia-wide map coverage at 1 : 2 million, while the Handbook is still very useful because of the detailed accounts of the morphology, micromorphology, and laboratory data for a large number of widespread Australian soils. A disadvantage of the Handbook is the lack of a key to the soil groups. The most comprehensive of the earlier New Zealand national soil classification systems is the New Zealand Genetic Soil Classification[6] reviewed by Hewitt[7] in 1992. In his classification, Taylor[6] developed what would now be called soil landscape models, in which soil groups were related to environmental factors employing the zonal concepts of the Russians. The classification by Taylor was first published in 1948 as a legend to the first National Soil Map, but with time, a number of weaknesses became apparent. Examples include the failure of the genetic scheme when applied at the scale of the farm paddock and the difficulty of soil correlation between regions. It became obvious that a new model was required that made provision for important classes of New Zealand soils.
NATIONAL SOIL CLASSIFICATION SYSTEMS IN THE MODERN ERA In the 1970s and 1980s, there was an increase in soil surveys in some Australian states, particularly Queensland and the Northern Territory, where the then-current Northcote and Stace, et al. systems were often found to be inadequate to cater for many ‘‘new’’ Australian soils, particularly in the wet tropics and in the subtropics. A soil classification committee with an Australia-wide charter was set up in the early 1980s to remedy the lack of an adequate, up-to-date national soil classification. Extensive field travel was carried out in most parts of Australia to gather field Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042642 Copyright # 2006 by Taylor & Francis. All rights reserved.
Classification Systems: Australian and New Zealand
231
Fig. 1 Schematic summary of the 14 orders of the Australian soil classification. (From Ref.[10].) (Note: this figure is not to be used as a key.)
and laboratory data to build up a database, which would eventually contain some 14,000 published and unpublished profiles, many with laboratory data; mainly chemical. The ‘‘First Approximation’’ of a new national scheme was first compiled in 1989 and was widely circulated in Australia for comment. Two further approximations were produced and circulated before the published version appeared in 1996 titled The Australian Soil Classification (ASC).[2] It should be noted that due assessment was made of two so-called international systems viz., Soil Taxonomy[8] and the subsequent revisions of most of its Orders, and the other major ‘‘international’’ system that of the FAO–UNESCO (1990) Soil Map of the World and its updated (1998) version titled World Reference Base for Soil Resources.[9] While these two so-called international schemes are of considerable value and interest for comparative purposes, it is more likely that most Australian pedologists would agree on the need for an appropriate national system that is
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regularly updated. The possibility of using methods of numerical classification was also examined, but was thought to be inappropriate because of the great variability and inconsistencies in the soil datasets, e.g., lack of representation of important groups of soils.
The Australian Soil Classification This scheme[2,10] is now widely used in most Australian soil surveys and pedological studies, primarily in an identification role. The scheme may be described as a multicategoric, hierarchical (order, suborder, great group, subgroup, and family), general purpose scheme with classes defined on the basis of diagnostic horizons or materials and their arrangement in vertical sequence as seen in an exposed profile. The classes are mutually exclusive and the allocation of new or unknown individuals to the classes is by means of keys. The scheme is
232
open-ended and new classes can be defined as knowledge increases, although these may not necessarily be added in sequence to the present list. Fourteen orders are currently defined (Fig. 1). A recent innovation is the development of an interactive key to The Australian Soil Classification available on CD-ROM.[11] The structure of the ASC has strong similarities with that of Soil Taxonomy, and although the emphasis is on field morphology, laboratory data have been used as appropriate. All technical terms are defined in a glossary. In a companion publication,[10] further descriptions of diagnostic horizons and materials as well as the general occurrence of each order are given except for Anthroposols where data were unavailable. The major classes of each order and the use of major attributes in the subdivision of the orders are discussed. The main chemical properties used are pH and exchangeable cations, with pH commonly being determined in the field. A table is provided giving approximate correlations between ASC orders, three other Australian classifications, and Soil Taxonomy orders. Perhaps the major benefit of the ASC is that it provides a means for efficient communication and a systematic framework for understanding and learning about the properties and inter-relationships of soils. Experience with the Factual Key[3] suggested retention of the use of color and generalized texture profiles at high levels in the hierarchy of the new system, although formal justification of such decisions is often difficult to demonstrate. Another feature of the ASC that partly overcomes some of the problems associated with hierarchies is the use of family criteria at any level of the system.
Classification Systems: Australian and New Zealand
one (order, group, subgroup, and series), with class distinctions based on diagnostic horizons and materials. Keys are provided to enable easy class definitions and identification. Total number of orders is 15: Allophanic Soils, Anthropic Soils, Brown Soils, Gley Soils, Granular Soils, Melanic Soils, Organic Soils, Oxidic Soils, Pallic Soils, Podzols, Pumice Soils, Raw Soils, Recent Soils, Semiarid Soils, and Ultic Soils. Accessory properties of the orders as well as concept, occurrence, and correlation with the earlier New Zealand Genetic Soil Classification and appropriate classes of Soil Taxonomy are also listed. The scheme is open-ended and new classes can be incorporated into the hierarchy.
CONCLUSIONS This brief review of the development of two national soil classification systems indicates the need for some taxa which are required for one country but not the other. Of the 15 New Zealand soil orders that have been defined, at least two (Allophanic Soils and Pumice Soils) are virtually absent in Australian soil landscapes. Conversely, some widespread Australian soils are only partly represented in the New Zealand system. Particular examples are the widespread Australian semiarid soils characterized by profiles which feature a clear or abrupt change to a textural B horizon, which is frequently sodic. Finally, there are some soils common to both countries that probably could be satisfactorily classified at the order level by the other system. A few such examples include Arthropic soils and Arthroposols, Gley soils and Hydrosols, Organic soils and Organosols, Oxidic soils and Ferrosols, and Podzols and Podosols.
New Zealand Soil Classification With the advent of Soil Taxonomy, New Zealand soil scientists became heavily committed to its international development, involving a five-year testing program in New Zealand. As in Australia, difficulties became apparent, particularly with regard to its complexity. The results of the investigations showed that Soil Taxonomy made inadequate provision for important classes of New Zealand soils, particularly in the case of Inceptisols. Much of the new order of Andisols was based on New Zealand, where Guy Smith spent 12 months studying these and other soils. The inadequacies of Soil Taxonomy and the older New Zealand genetic classification to serve as an up-to-date national classification led to the development and publication of new material, largely through the efforts of Hewitt.[7,12–15] The most recent version[13] has a helpful introductory section in which concepts, objectives, and principles are outlined. The scheme is a hierarchical
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REFERENCES 1. Isbell, R.F. A brief history of national soil classification in Australia since the 1920’s. Aust. J. Soil Res. 1992, 30, 825–842. 2. Isbell, R.F. The Australian Soil Classification; CSIRO Publishing, 1996. 3. Northcote, K.H. A Factual Key for the Recognition of Australian Soils, 4th Ed.; Rellim Technical Publications: South Australia, 1979. 4. Stace, H.C.T.; Hubble, G.D.; Brewer, R.; Northcote, K.H.; Sleeman, J.R.; Mulcahy, M.J.; Hallsworth, E.G. A Handbook of Australian Soils; Rellim Technical Publications: South Australia, 1968. 5. Stephens, C.G. A Manual of Australian Soils, 3rd Ed.; CSIRO: Melbourne, 1962. 6. Taylor, N.H. Soil Map of New Zealand, 1:2,027,520 Scale; DSIR: Wellington, 1948. 7. Hewitt, A.E. Soil classification in New Zealand: legacy and lessons. Aust. J. Soil Res. 1992, 30, 843–854.
Classification Systems: Australian and New Zealand
8. Soil Survey Staff. In Soil Taxonomy, a Basic System of Soil Classification for Making and Interpreting Soil Surveys; USDA Agriculture Handbook No. 436; U.S. Government Printing Office: Washington, 1975. 9. FAO. World Reference Base for Soil Resources; FAO World Soil Resources Report 84, 1998. 10. Isbell, R.F.; McDonald, W.S.; Ashton, L.J. Concepts and Rationale of the Australian Soil Classification, ACLEP; CSIRO Land and Water: Canberra, 1997. 11. Jacquier, D.W.; McKenzie, N.J.; Brown, K.L.; Isbell, R.F.; Paine, T.A. The Australian Soil Classification: An Interactive Key; CSIRO Publishing, 2001.
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12. Hewitt, A.E. New Zealand Soil Classification (Version 2.0); DSIR Division of Land and Soil sciences Technical Record DN 2; Department of Scientific and Industrial Research: Wellington, 1989. 13. Hewitt, A.E. New Zealand Soil Classification; Landcare Research Science Series No. 1; Manaaki Whenua Press: Lincoln, 1998. 14. Hewitt, A.E. Methods and Rationale of the New Zealand Soil Classification; Landcare Research Science Series No. 2; Manaaki Whenua Press: New Zealand, 1993. 15. Clayden, B.; Webb, T.H. Landcare Research Science Series No. 1; Manaaki Whenua Press: Lincoln, New Zealand, 1994.
Classification Systems: French Jean-Paul Legros Science du Sol, INRA, Montpellier, France
INTRODUCTION France is a very small country. But it was previously the head of an empire covering a part of Africa and Asia. During the International Exhibition of 1900, in Paris, Dokoutchaev explained his concepts concerning pedology, attracting the interest of the French scientists on this subject. The two facts explain the interest of French scientists in soil classification.
BRIEF HISTORY From the beginning of pedology, the French scientists used genetic classifications of soils in relation to the work of the Russian school of Dokuchaiev (1846– 1903) and Glinka (1867–1927). For example, Vale´rien Agafonoff (1863–1955), a Russian soil scientist, came to Paris fleeing his country during the revolution of 1917. He built one of the first soil maps of France with the corresponding legend (created in 1928, but published mainly in 1936 after improvements).[1–3] Using the previous and successive works of Lagatu (1862–1942),[4,5] Demolon (1881–1954), Kubie´na (1897–1970), Erhart (1898–1982) and several German authors, Georges Aubert (born in 1913), and Philippe Duchaufour (1912–2000) presented a first French classification in Paris, in 1956, during the Sixth International Congress of Soil Science. A second version of this system was presented in 1962 and is known as ‘‘Aubert-Duchaufour classification.’’ In 1960, Duchaufour published his famous ‘‘Pre´cis de Pe´dologie,[6]’’ which popularized his classification system to a much wider audience. Then, in 1967, the whole French scientific community collaborated and completed the system which became the ‘‘Classification of the CPCS’’ (Commission de Pe´dologie et de Cartographie des Sols). This document was used for 20 yrs and popularized a vocabulary presently used in the ordinary pedological language of French scientists, e.g., sol brun, ranker, rendzine, etc. During this period, the USDA system and the FAO Soil Legend were developed (1960 and 1981). Simultaneously, the development of Computer Science and Statistical Science demonstrated that the soils could be classified in a more objective way by searching for Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042644 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
the mathematical similarities between taxa and objects rather than trying to enter a soil in a more or less adapted taxon of a rigid classification system. In this context, since 1986, the French community met, worked, and presented a first version of ‘‘Re´fe´rentiel Pe´dologique’’ (RP) in 1992. A second version was produced in 1995,[7] with an English translation in 1998,[8] and followed by Italian and Russian translations (2000). Because several French scientists were involved in the development of both the new French trials and the World Reference Base (WRB),[9] the two systems have many similarities in both philosophy and organization, although not necessarily in the details of vocabulary. Thus, it is logical to review the RP in comparison with the WRB.
COMPARING THE RP AND THE WRB Principal points of comparison are the following:
The 40 diagnostic horizons of the WRB are replaced by the 73 ‘‘Horizons de Re´fe´rence’’ of the RP.
The 30 reference soil groups of the WRB are replaced by the 30 ‘‘Grands Groupes de Re´fe´rences’’ (major groups of references or ‘‘GER’’). But these 30 categories do not match exactly because, in the French system, the tropical soils are not considered. This last point is regretted[10] (10), considering the large vast experience of French scientists in Africa. Theses 30 Groupes are divided into 102 ‘‘Sols de Re´fe´rence.’’
The WRB ‘‘Diagnostic properties,’’ ‘‘Diagnostics materials,’’ ‘‘Formative elements,’’ and ‘‘Prefixes’’ correspond to the ‘‘Qualificatifs’’ (Qualifiers) of the RP. In the RP, all these elements are grouped in a single list of 235 terms. The more original point of the RP is that a Diagnostic horizon alone is in general, not sufficient to recognize a Re´fe´rence. Several Diagnostic horizons are associated to identify a Solum (profile development as A, E, B, C including a part of the underlying rock).[11] For this reason, the ‘‘Horizons de Re´fe´rence’’, in the RP, are defined considering strongly their relative development (A, B, C horizons, 247
248
Classification Systems: French
etc.). This indicates clearly that a part of the previous genetic approach remains inside the RP. Its organization is presented in Fig. 1. Even if it is not fully completed, the RP, richer in taxa and qualifiers for a smaller part of the world, may be considered to be more precise than the WRB. It is organized in three logical levels that are not truly hierarchical. It allows the user to identify a soil as an intermediate between two taxa, e.g., a ‘‘REGOSOL– CRYOSOL’’. Table 1 shows the approximate links between WRB and RP at the level of GER, Re´fe´rences and Groups. The most specific Re´fe´rences of the RP if we compare with WRB are presented in Table 2 with short explanations. All this demonstrates that it is very easy to go from one system to the other at the level of Groups and Re´fe´rences even if ‘‘Calcisol’’ is a false cognate. (Calcisol means calcareous in WRB but saturated and not calcareous in the RP.) The situation is more complicated at the level of soil types. Many of the qualifiers seem similar, but this may not truly be the case. Table 3 shows some of the difficulties which may be encountered. Table 4 characterizes the French soils using the RP system. The data were kindly provided by the Service d’Etude des Sols et de la Carte Pe´dologique de France (Orle´ans).
Table 1 Relationships between the WRB groups (left) and the GER or the Re´fe´rences of the RP (right) Re´fe´rentiel pe´dologique
WRB Histosol
Histosol
Cryosol
Cryosol
Anthrosols
Anthroposols
Leptosols
Lithosols (superficial) Rankosols (on acid rocks) Organosols (rich in organic matter) Rendosols (on calcareous rocks)
Vertisols
Leptismectisols (A=C or A=R profile) Vertisols (with B horizon)
Fluvisols
Fluviosols Thalassosols (estuarine=marine soils)
Solonchaks
Salisols
Gley soils
Re´ductisols (dominant reduction) Re´doxisol (dominant oxidation)
Andosols
Andosols Vitrosols (with glass)
Podzols
Podzosols
Plinthosols
Not already studied
Ferralsols
Not already studied
Solonetz
Sodisols
Planosols
Planosols
Chernozems
Chernosols
Kastanozem
DISCUSSION To pass from a purely genetic classification to an international reference system, such as the WRB, was rather a long journey for the French pedological community.[12] The construction of the RP, initiated by Denis Baize and Michel-Claude Girard, was a good way to test the possibility of this large change in the French method of thinking.
Fig. 1 Organization of the Re´fe´rentiel Pe´dologique.
Copyright © 2006 by Taylor & Francis
Phaeozem
Phaeosols
(Greyzems)
Grisols
Gypsisols
Gypsosols
Durisols
Not already studied
Calcisols
Rendosol (rendzine) Rendisols (same morphol., saturated) Calcosols (calcareous with B) Dolomitosols (with MgCO3) Calcisols (noncalcareous, saturated) Magnesisols (with Mg2þ on clay) Calcarisols (calcaric within 25 cm)
Albeluvisols
Luvisols (for a part)
Alisols
Not already studied
Nitosols
Fersialsols (for a part)
Acrisols
Not already studied
Luvisol
Luvisol
Lixisols
Not already studied
Umbrisols
Alocrisols humiques, rankosols
Cambisols
Brunisols Pelosols (rich in clay but not 2=1)
Arenosol
Arenosol
Regosol
Re´gosol
Classification Systems: French
249
Table 2 Specific Re´fe´rences in the RP Alocrisols
Table 4 Inventory of the French soils using the RP (from INRA-SESCPF)
Acidic but without argic horizon (i.e., different from the WRB ‘‘Acrisols’’)
Colluviosols
Re´fe´rentiel Pe´dologique
From colluvium, i.e., on slopes, in parallel with fluviosols From Peyre ¼ stone in some local French languages, i.e., with important coarse fraction
Peyrosols
Veracrisols
Sort of Acrisols rich in earth worms
Recently (year 2005, June), the French community of Soil Science fall in agreement (vote in an Administrative Council of AFES) on the following ideas:1) the RP system will be updated adding the tropical soils that were so precisely studied in the period of the French African Empire and 2) this new version of the RP will be built taking in consideration the WRB to get a full compatibility between the two systems. Working in such a way, French scientist will conserve their national system allowing them to focus on such taxa for regional reasons, but preserving the international dialog through the WRB.
Corresponding WRB group
% of France
Calcosols, Brunisols
48.5
Cambisols
Luvisols
14.5
Luvisols
Rendosols
8.3
Calcisols (p.p)
Fluviosols
7.8
Fluvisols
Podzolized luvisols
6.4
Albeluvisols
Podzosols
5.6
Podzols
Lithosols
2.3
Leptosols (p.p)
Rankosols
1.8
Leptosols (p.p)
Andosols, vitrosols
1.0
Andosols
Are´nosols
0.8
Arenosols
Re´doxisols, Re´ductisols
0.4
Gleysols
Re´gosols
0.4
Regosols
Salisols
0.4
Solontchaks
Histosols
0.3
Histosols
Phaeosols
0.1
Phaeozems
Vertisols
0.1
Vertisols
Planosols
0.1
Planosols
Autres sols et surfaces
1.2
Others soils and surfaces
CONCLUSIONS in the RP, at an international level, seems limited because of its great similarity with the WRB.
For the French scientific community, the development of the RP is a good opportunity to work together on the concepts of the soil classifications and to study the genesis and the functioning of the soils identified in France. Moreover, in the RP volume, the texts that present the Andosols (the soils with hydromorphic features, and the different kinds of humus) are valuable contributions to Pedology. Nevertheless, the interest
ARTICLE OF FURTHER INTEREST World Reference Base for Soil Resources, p. 1918. Classification: Need for Systems, p. 227.
Table 3 Differences between qualifiers in WRB and RP Examples Case
Problem
WRB terminology
RP terminology
1
Term specific of one of the two systems (scarce case)
Carbic
Clinohumic (isohumic)
2
Same meaning but different terms (scarce case)
Alumic (Al sat >50%)
Aluminic (Al
3
Same name but slightly different meanings (general case)
Magnesic Ca2þ=Mg2þ 0.84 mm in diameter, resists erosion from all but the highest winds.[9] Clods of this size are not easily moved by wind, and they protect smaller clods and particles in their lee. Loams, silt loams, and clay loams tend to form the most stable aggregates and are, therefore, the least affected by erosive winds. The type of tillage equipment used has a definite influence on soil cloddiness and surface roughness. Smika and Greb[15] found that tillage by machines other than the chisel tend to reduce the non-erodible soil aggregation. One-way, offset or tandem disks leave a smooth surface. Subsurface sweeps, because they do not disturb the soil surface, do not create a rough, ridged soil surface, but they do maintain a greater vegetative roughness by allowing some of the vegetation to remain erect.[16]
ROUGHENING THE LAND SURFACE Soil surface roughness is composed of anchored vegetative material, soil ridges, soil clods, or combinations of all three. All help to control wind erosion by lowering the wind velocity near the soil surface and by sheltering erodible soil fractions.[17] Tillage implements form ridges and depressions which alter wind velocity. The depressions behind the ridges trap saltating soil particles and stop the normal build-up of eroding material downwind. Emergency Tillage Emergency tillage is a last-resort wind erosion control practice that can provide a rough, cloddy surface. It is usually carried out when vegetative cover is depleted by excessive grazing, drought, improper or excessive tillage, or by growing crops that produce little or no residue (Fig. 6). Emergency tillage is an inadequate wind erosion control measure and its only purpose is to create a temporary erosion-resistant soil surface. Implements such as listers, chisels, shovels and ‘‘sandfighters’’ should traverse fields at right angles to erosive winds to roughen the soil surface and bring clods to the surface.[9] Listers and narrow chisels were found by Chepil and Woodruff[16] to have the most effective tillage points for emergency tillage. Listers provide a high degree of roughness, and in extremely sandy soils,
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601
Fig. 6 Field following emergency tillage. (Courtesy of USDA.)
where clods can be produced only by deep tillage, they are the most effective tools available. Chisel cultivators are more widely used because they require less power and destroy less growing crop than listers.
RESHAPING THE LAND TO REDUCE EROSION ON KNOLLS Reshaping the land by leveling knolls and benching slopes to shorten the unsheltered distance is an option in wind erosion control, but is usually not economical or practical. Because land reshaping is very costly, other effective control measures, such as no-till and seeding to permanent grass, are usually options that are more viable. Hills and knolls affect tillage system requirements indirectly by influencing wind shear stress. When the wind blows over a hill, streamlines of airflow are squeezed together, which increases the wind velocity and shear stress, thereby increasing the erosion potential on the windward slope and hilltop. Consequently, this increases the amount of residue, cloddiness, or roughness needed to control wind erosion on the knoll.
OTHER WIND EROSION SITUATIONS Wind Erosion on Irrigated Land Wind erosion on irrigated land can be a serious problem in areas characterized by variable high-wind velocities, where the soils are organic or quite sandy and low in organic matter or where crop residues are inadequate. Under certain conditions it is impractical and wasteful of water to irrigate frequently enough to prevent a finely pulverized surface soil from blowing.
602
The depth of drying may only be a fraction of an inch and the soil below this may be wet, but if the immediate surface is dry and the wind is strong enough, the top layer can erode unless the soil particles are consolidated into clods or protected by vegetation. The basic element in erosion control by tillage on irrigated land, as on dryland, is the creation of a rough, cloddy surface which will resist the force of the wind, decrease its velocity at the ground level and trap moving soil. Sandy soils, usually found in irrigated areas, are far more difficult to protect by emergency measures than fine-textured soils. Wind Erosion Control on Sand Dunes and Other Problem Areas Wind erosion control on sand dunes and other problem areas require measures that are more intensive to get sand dunes in check. Dunes lack a soil profile because they are unstable and underdeveloped. The sand is fine, loose and easily moved by wind. It has no organic matter, and consequently retains little moisture for plants and has inherently low fertility. Sand dunes and drift areas often require artificial barriers or cover for stabilization before vegetation can be established. These include oil, clay gravel, picket fence, brush, straw, and hay. Clay is effective, but is expensive. Hay or straw can be used as temporary mulches on blowout or small areas of dune sand at road cuts, around dwellings and other disturbed areas. They provide some organic matter, which is critical for successful dune plantings. The establishment of permanent vegetation is the final objective in the stabilization of dunes. Other Non-Vegetative Erosion Protection Some of the non-vegetative and processed vegetative materials used are gravel and crushed rock, various surface films such as resin-in-water emulsion (petroleum origin), rapid-curing cutback asphalt, asphaltin-water emulsion, starch compounds, latex-in-water emulsion (elastomeric polymer emulsion), by-products of the paper pulp industry, and wood cellulose fiber.[2] Several of these spray-on adhesives are available for temporary wind erosion control of vegetable seedlings on mineral soils. Some of the adhesives are relatively expensive, but a few are economically feasible on high-value crops threatened by serious blowing that cannot be controlled by other methods.
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Erosion by Wind: Control Measures
REFERENCES 1. Lyles, L. Basic wind erosion processes. Agric. Ecosystems Environ. 1988, 22=23, 91–101. 2. Woodruff, N.P.; Lyles, L.; Siddoway, F.H.; Fryrear, D.W. How to Control Wind Erosion; U.S.D.A., SEA Agric. Inf. Bull. No. 354; U.S.D.A., A.R.S.: Washington, D.C, 1972; 22 pp. 3. Greb, B.W. Reducing Drought Effects on Cropland in the Western-Central Great Plains; U.S.D.A., SEA Agric. Inf. Bull. No. 420; Washington, D.C, 1979; 31 pp. 4. Haas, H.J.; Willis, W.O.; Bond, J.J. Summer Fallow in the Western United States; Agriculture Research Service Conservation Research Report No. 17; U.S.D.A.: Washington, D.C, 1974; 149–160. 5. Watson, S., Ed.; Kansas No-Till Handbook; Kansas State University: Manhattan, KS, 1999; 72 pp. 6. Rice, R.W. Fundamentals of No-Till Farming; American Association for Vocational Instructional Materials: Winterville, 1983; 148 pp. 7. Crovetto, C. Stubble over the soil. In The Vital Role of Plant Residue in Soil Management to Improve Soil Quality; Amer. Soc. Agronomy: Madison, WI, 1996; 245 pp. 8. Domitruk, D., Crabtree, B., Eds.; Zero Tillage. Advancing, the Art; Manitoba-North Dakota Zero Tillage Farmers Association: Brandon, Manitoba, 1997; 40 pp. 9. Tibke, G. Basic principles of wind erosion control. Agric. Ecosystems Environ. 1988, 22=33, 103–122. 10. Skidmore, E.L.; Hagen, J.L. Reducing wind erosion with barriers. Trans. ASAE 1977, 20, 911–915. 11. Siddoway, F.H.; Fenster, C.R. Soil conservation: western great plains. In Dryland Agriculture; Dregne, H.E., Willis, W.O., Eds.; Monograph No 23; Amer. Soc. Agronomy: Madison: WI, 1983; 231–246. 12. Chepil, W.S. Wind erosion control with shelterbelts in North China. Agron. J. 1949, 41, 127–129. 13. Black, A.L.; Bauer, A. Soil conservation: northern great plains. In Dryland Agriculture; Dregne, H.E., Willis, W.O., Eds.; Monograph No 23; Amer. Soc. Agronomy: Madison, WI, 1983; 247–257. 14. Aase, J.K.; Siddoway, F.H.; Black, A.L. Effectiveness of grass barriers for reducing wind erosiveness. J. Soil Water Conserv. 1985, 40, 354–360. 15. Smika, D.E.; Greb, B.W. Nonerodible aggregates and concentration of fats, waxes and oils in soils as related to wheat straw mulch. Soil Sci. Soc. Am. Proc. 1975, 39, 104–107. 16. Chepil, W.S.; Woodruff, N.P. The physics of wind erosion and its control. Adv. Agron. Water Conserv. 1963, 15, 211–302. 17. Armbrust, D.V.; Chepil, W.S.; Siddoway, F.H. Effects of ridges on erosion of soil by wind. Soil Sci. Soc. Am. Proc. 1964, 28, 557–560.
Erosion by Wind: Effects on Soil Quality and Productivity John Leys Department of Land and Water Conservation, Gunnedah, New South Wales, Australia
INTRODUCTION
Soil Texture Changes
Accelerated erosion on agricultural lands has adverse effects on soil quality and productivity through the removal of soil particles and nutrients. The majority of reviews of this topic have concentrated on the impact of water erosion on soil and crop productivity.[1,2] However, there is a growing number of research on the impact of wind erosion on soil quality and productivity, which is the focus of this entry. Wind erosion reduces soil quality and production using a mechanism different from that of water erosion. Water erosion removes the soil en masse, while wind erosion winnows the finer=lighter particles from the surface, leaving the larger (generally inert) particles behind. As a result, wind erosion removes topsoil[3] and reduces the soil clay and silt content[4] and the organic matter.[5] Wind erosion also has an impact on crop productivity. It sandblasts emerging crops,[6] reshapes the land surface, thereby making it difficult to traverse with wide agricultural implements, buries or undermines infrastructure such as fences and roads, and buries adjacent land with sand drift. This results in limiting the drifted land’s production in the short term.[7] Off-site impacts will not be discussed here, although wind erosion also has considerable off-site impact—e.g., reduces visibility,[8] deposits unwanted dust and off-farm associated contaminants off-farm, and raises airborne particulate levels,[9] with particle sizes less than 10 mm (PM10), which can have adverse health effects.[10]
The impact of erosion on soils has been measured over many years by using many different methods. Longterm analysis of soils exposed to wind erosion[11] showed a decline in the fertility and particle size distribution (PSD) of the surface soil. Over a 36-year period, a 6.5% increase in the sand fraction of the top 0–10 cm has been reported for midwestern U.S.A.[12] The comparison of the PSD of a soil that had been farmed for 30 years and had suffered periodic erosion with that of an adjacent soil under native vegetation,[13] revealed a loss of fines in the 10–100 mm fraction, as well as an increase in the coarse 350–1000 mm fraction (Fig. 1). Increases in the saltation fraction (>250 mm), and reduction in the 75–210 mm fraction, have been reported for the top 1 cm soil layer over a 15-week period for southeastern Australia.[3] Further research at the same site using a portable field wind tunnel indicated an increase in the dominant sediment population of PSD of the surface soil layer (approximately 0–500 mm depth) after a 30-min simulated erosion event. The analysis indicates that for the soil cultivation ridges, the proportion of the 300 mm sediment population increased from 60% in the parent soil to 86% after the simulated erosion. In the cultivation furrows, the 420 mm population increased from 0% to 85%. Analysis of the eroded sediments indicated that >78% of material being eroded fell within the 180 mm population, compared to 29% in the parent soil. The increase in the coarser fractions of the surface soil and the high proportion of finer fractions in the eroded sediment imply that wind erosion is winnowing the fines.
SOIL QUALITY Eroded Sediments Soil quality is generally adversely affected by wind erosion via the removal of soil fines (clay, silt, and organic fractions). Soil texture changes are largely irreversible, unless topsoil is imported to the site. Quantification of the changes in soil texture, as well as identifying the eroded fractions in the eroded sediments, indicates the magnitude of the decline in soil quality brought about by wind erosion. Descriptions of soil texture changes and the eroded sediments will be presented in the next two sections. Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042680 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
A large number of studies in North America,[14] Belgium,[15] Nigeria,[16] Australia,[3] and China[17] show that the particle size decreases as the height increases, indicating a selective sorting of the eroded particles. When the vertical component of the wind exceeds the fall velocity of the eroded particles, they are removed from the site along with their associated nutrients. Australian results indicate that for a one-week period of monitoring, 27% of the total eroded sediment is in 603
604
Fig. 1 Particle size distribution of two adjacent soils. One has been farmed for 30 years and has undergone repeated erosion; the other is under native vegetation. The PSDs show an increase in the coarse fraction (arrow a) and a decrease in the finer fraction (arrow b) in the eroded soil.
the suspension fraction and thus, are removed from the eroded field.[3] These studies further highlight the winnowing action of the wind erosion processes and the potential loss of soil and nutrients.
SOIL PRODUCTIVITY When soil is eroded from a site, there is often a subsequent decrease in rooting depth and available water holding capacity.[13] There is also a loss of nutrients and a subsequent decline in soil productivity. So if there is wind erosion, where does the nutrient go and how much impact does it have on crop production? Soil Nutrient Loss There is considerable evidence that wind-eroded sediments are enriched with nutrients. The nutrient loss has been measured at the site of dust emission, at various heights above the eroded surface, and downwind sites of the eroded area, both immediately adjacent to drift banks of soil and from deposited dust. It is important to examine the magnitude of this nutrient loss. The nutrient content and particle size of eroded sediments collected at 0–0.5 m height during wind tunnel tests were similar to source sediments.[18] However, if the sediments are sieved and the 11.5% protein, nitrogen supply at the higher level of sufficiency and luxury range is economically preferred. Yet high soil nitrate-N fertility may lead
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to excess of nitrate-N in soil and, consequently, to denitrification (greenhouse effect) and leaching. Excess nitrate-N in surface water bodies causes algal blooms and in drinking water causes methemoglobinemia in infants. Also, adverse environmental and health impacts occur when soil nutrient fertility is in toxic range (Fig. 2), especially for heavy metals, either because of human consumption of product or on ecosystems.
PERSPECTIVES Soil fertility evaluation has evolved in the last two centuries, from a major concern for enhancing crop production to that of maintaining environmental integrity. With increasing population, crop production will remain the main objective of managing the soil fertility. However, with the recent advances in multielement extractants and analysis and remote sensing and precision technologies for site-specific soil fertility evaluation, it is possible to meet the twin goals of economic optimum yields and minimal environmental pollution. By managing soil fertility this way, sustainable use of land, water, and nutrients is also ensured, resulting in enhanced soil and water quality for the current and future generations. In spite of the advances in sensor and analytical technologies, however, the challenge lies ahead in developing soil nutrient tests that closely mimic nutrient uptake by a crop.
CONCLUSIONS Significant progress has been made in soil fertility evaluation systems in last two decades because of valuable
Fertility Evaluation Systems
contributions made by ecologists and geographers, besides the continuing interest from agronomists and soil scientists. Consequently, a broad spectrum of technologies is being applied to soil fertility evaluation for sustainable natural resource management, food and fiber production, and ecologically sustainable practices for the benefit of both rural and urban communities. Further refinements in soil fertility evaluation systems would come from the integrative use of both classical and spectral technologies, and spatial and computational capacities for their appropriate applications to ecosystems and landscapes.
REFERENCES 1. Russell, E.W. Soil Conditions and Plant Growth, 10th Ed.; Longman: London, 1973; 49–50. 2. Mitscherlich, E.A. Das Gesetz des Minimums und das Gesetz des Abnehmenden Bodenertrages. Landwirtschaftliche Jahrbu¨cher 1909, 38, 537–552.
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3. Robinson, D.J.; Reuter, J.B., Eds. Plant Analysis: An Interpretation Manual, 2nd Ed.; CSIRO Publishing: Melbourne, 1997; 1–572. 4. Black, C.A. Soil Fertility Evaluation and Control; Lewis Publishers: Boca Raton, FL, 1993; 1–746. 5. Havlin, J.L.; Beaton, J.D.; Tisdale, S.L.; Nelson, W.L. Soil Fertility and Fertilizers, 6th Ed.; Prentice Hall: Upper Saddle River, New Jersey, 1999; 1–499. 6. Peverill, K.I.; Sparrow, L.A.; Reuter, D.J., Eds. Soil Analysis: An Interpretation Manual; CSIRO Publishing: Melbourne, 1999; 1–369. 7. Dalal, R.C.; Hallsworth, E.G. Evaluation of the parameters of soil phosphorus availability factors in predicting yield response and phosphorus uptake. Soil Sci. Soc. Am. J. 1976, 40, 541–546. 8. Sanchez, C.A.; Couto, W.; Buol, S.W. The fertility capability soil classification system: interpretation, application and modification. Geoderma 1982, 27, 282–309. 9. Sudduth, K.A.; Hummel, J.W.; Birrel, S.J. Sensors for site-specific management. In The State of SiteSpecific Management for Agriculture; Pierce, F.J., Sadler, E.J., Eds.; ASA=CSSA=SSSA: Madison, 1997; 183–210.
Fertility: Environmentally Compatible Management Bal Ram Singh Agricultural University of Norway, Aas, Norway
INTRODUCTION Soil Fertility in the Past In writings dating back to 2500 B.C. the fertility of land is mentioned. Herodotus, the Greek historian, traveling through Mesopotamia some 2000 yr later reported the phenomenal yields obtained by the inhabitants of this land. Later Theophrastus (372–287 B.C.) recommended the abundant manuring of thin soils but suggested that rich soils be manured sparingly. During the seventeenth and eighteenth centuries, agricultural writings reflected that plants consisted of one substance, and most of the workers were searching for this principle of vegetation during this period. It was not until the later half of nineteenth and the beginning of the twentieth century that some progress was made to understand the subject of plant nutrition and crop fertilization. It was Justus von Liebig (1803–1873), a German chemist, who effectively deposed the humus myth and eventually developed the law of minimum. The law says that the growth of plants is limited by the plant–nutrient element present in the smallest quantity, all others being present in adequate amounts. These developments led to a rapid increase in chemical fertilizer’s use. Soil Fertility in Modern Times With advances in our knowledge with regards to various processes affecting the nutrient dynamics in soils, the definition of soil fertility is also refined. Soil fertility integrates the basic principles of soil biology, chemistry and physics to develop the practices needed to manage nutrients in a profitable and environmentally sound manner. The main focus of soil fertility is to manage nutrient status in soils to create optimum conditions for plant growth. Two fundamental principles underlay the study of soil fertility. First is the recognition that optimum nutrient status alone will not ensure soil productivity. Other factors, such as soil moisture and temperature, soil physical conditions, soil acidity and salinity, and biotic stress can reduce the productivity of even more fertile soils. Second is the realization that modern soil fertility practice must stress soil productivity and environmental protection.[1] Taking the second realization in perspective, it is imperative that soil 674 Copyright © 2006 by Taylor & Francis
fertility in relation to agricultural sustainability and environmental protection will be the main focus of this paper.
SOIL FERTILITY AND AGRICULTURAL SUSTAINABILITY In recent years, a new dimension to soil fertility in relation to agricultural production has been added. It is the concept of ‘‘sustainability,’’ which has been defined and interpreted differently by different workers. Okigbo[2] after analyzing the various definitions of sustainable agriculture by different workers defined ‘‘a sustainable agricultural production system as one that maintains an acceptable and increasing level of productivity that satisfies prevailing needs and is continuously adapted to meet the future needs for increasing the carrying capacity of the resource base and other worthwhile human needs.’’[2] The sustainability of a production system is location specific and is determined to a greater degree by an interaction among several production factors, viz. physiochemical (soil, climate, radiation etc.) biological (crop species, weeds and pests etc.), management and socioeconomic elements. Maintenance and management of soil fertility is central to the development of sustainable food production systems. Sustainability is dependent to a large degree on recycling the inputs into a production system, thereby increasing efficiency of output per unit of resource input. Soil fertility management is concerned with the essential plant nutrients, their amounts, availability to crop plants, chemical reactions in soil, loss mechanisms, processes making them unavailable or less available to crop plants, and ways and means of replenishing them in these soils.[3]
ESSENTIAL NUTRIENTS Because soil fertility involves management of nutrients required for plant production, it is important to describe briefly the elements, which are considered essential for plant growth. The essential nutrients required by higher plant are exclusively of inorganic nature, and Arnon and Stout[4] proposed the term essential nutrient (element). The essential element must meet three criteria to be Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001622 Copyright # 2006 by Taylor & Francis. All rights reserved.
Fertility: Environmentally Compatible Management
considered essential: 1) a given plant must be unable to complete its life cycle without the presence of mineral element in question; 2) the function of the element cannot be replaced by another element; and 3) the element is directly involved in the nutrition of the plant—for example as a component of an essential plant constituent such as enzyme—or must be required for a distinct metabolic step such as an enzyme reaction. Some elements, which either compensate for the toxic effect of other elements or they simply replace mineral elements in some of their less specific functions, such as maintenance of osmotic pressure, can be described as beneficial elements. Out of a large number of elements found in plants, 14 mineral elements are recognized as essential, whereas the requirement of chlorine and nickel is yet restricted to a limited number of plant species. The plant nutrients may be divided into macronutrients (N, P, S, K, Mg, Ca), micronutrients (Fe, Mn, Zn, Cu, B, Mo, Cl, Ni) and beneficial elements (Na, Si, Co). The last three elements have been found essential only for some plant species, for example, Na for plants with C4 photosynthetic pathway, Si for rice, and Co for fixation of atmospheric N by rhizobia and blue green algae, but they have not yet been included in the list of essential nutrients.[3]
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Soil Quality The export of agricultural produce takes with it large amounts of nutrients (especially N, P, K, and S) and if these nutrients are not replenished, soil organic matter (SOM) and the fertility of the soil will decline and the soil will degrade. A number of such examples from the subsistence farming of the tropics are available, where ‘‘nutrient mining’’ of soils has been responsible for decline in soil fertility and soil quality leading to loss of productivity.[5] The rapid loss of SOM of the topsoil after clearing of the natural vegetation or under continuous cultivation is a common phenomenon in Africa. In Zambia it was found that the SOM content dropped from 59 to 32 Mg ha1 after 17 yr of cultivation of a newly cleared land, which represented an average loss of 1.6 Mg ha1 y1.[6] On the other hand, long-term studies carried out in temperate regions have shown that organic matter of soil can be maintained or raised modestly by proper fertilization and especially by organic manures and crop residue management.[7] Any management practice that results in an increase in the crop residues returned to soil will have a positive influence on soil organic matter,[7] which in turn will affect soil aggregation and related properties such as soil structure, erodibility, workability, and water infiltration. Growing of legumes is an effective way for promoting good soil aggregation and for reversing degradative trends.
MANAGEMENT OF SOIL FERTILITY AND THE ENVIRONMENT Water Quality As pointed out by Sims[1] that modern soil fertility in addition to involving soil productivity, must also include protection of the environment and thus the environmental aspects related to soil fertility are described under this section. Long-term use of organic and inorganic fertilizers to agricultural soils has led to slow build up of nutrient reserves and especially under temperate conditions. The same nutrients, which are considered essential for plant growth and crop production, if lost from the system, can create a concern for the environment. Increased use of fertilizers for meeting the world food demand and recycling of on farms (manures and slurries) and off farms organic wastes (municipal and industrial sludges) on agricultural lands in the last three decades have resulted in some undesirable effects on the environment in intensively cultivated areas. This has created greater awareness for environmental issues not only among scientists and policy makers but also among general public. Although there are a number of issues related to soil fertility and the environment, emphasis is placed on four main concerns of environmental protection, viz. soil quality, water quality, air quality, and heavy metals and food concerns.
Copyright © 2006 by Taylor & Francis
The major concerns with regards to water quality are accelerated eutrophication of surface waters and nitrate (NO3) content of drinking water. Eutrophication, the rapid growth and decay of aquatic vegetation, is most often limited by P and sometimes by N concentration in water. The NO3 concentration of 10 mg L1 in drinking water is considered safe but higher concentration can cause methaemoglobinaemaia (reduced carrying capacity of blood for O2) in children. Both over fertilization and under fertilization can lead to N losses. Losses occur either as runoff to surface water or as leaching to underground waters. Under normal conditions, runoff losses in watersheds are low (e.g., 10 mg L1). Much of the N transported in runoff is particulate N associated with the sediments and it can range from 0 to 7 kg N ha1.[8] These losses can be reduced by incorporation of fertilizer and providing a good vegetation cover. Much of N losses occur through leaching but there is a large variation in the quantities of N lost in leaching depending on the amount of N fertilizer applied, soil type, crop grown and climatic conditions. Letey et al.[9] reviewed NO3 concentration in tile effluents from 55 sites of
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California; the concentration ranged from 1 to 196 mg L1, with only one-quarter of the sites averaging 10 mg L1) nitrate levels.[10] From surface water viewpoint, P is the element of primary concern, since it is considered limiting for eutrophication. Excessive application of organic and inorganic fertilizers can result in building of P near the soil surface, which is subjected to soil erosion leading to P losses to surface waters. In aquatic ecosystems of southwestern Australia an excess of nutrients has caused serious eutrophication, which was manifested by excessive growth and accumulation of green and blue green algae.[11] Phosphorus is generally the limiting nutrient for algae growth and phosphatic fertilizers applied to nutrient-deficient, leaching, sandy soils were the main source of P in these ecosystems of Australia.
Air Quality The primary goal of good nutrient management and especially N should be to maximize N uptake at critical growth stages and to minimize transformation processes, which lead to formation of ‘‘greenhouse gases.’’ The main N-containing greenhouse gas is N2O. The N2O produced during nitrification and denitrification contributes to global warming and stratospheric ozone depletion. Annual losses of N as N2O from fertilized field soil can be as high as 40 kg h1 compared to that from unfertilized soils being 6.0 can help limit their release in the soil and availability to plants. A general advantage of organic fertilizers can be cost of the nutrient, but that is not always the case. It largely depends on the proximity of the organic fertilizer to the site of application and the value of the organic. In cases where a material must be placed in a landfill, the material may have a negative value due to the cost and maintenance of that landfill. If so, a material may be obtained at little or no cost, or even at a negative cost. As organic fertilizers generally have lesser nutrient values than modern manufactured inorganic fertilizers, the cost of transportation per unit of nutrient is often the controlling factor in value of the fertilizer. A second potential advantage of organic fertilizers is that they may provide nutrient release over an extended period of time; in particular, nitrogen (N) can be mineralized over a season to eliminate the need for repeated applications. Soil organic matter can be increased when organic fertilizers are applied at sufficient rates. The value of soil organic matter is well recognized, but the ability of added organic matter to substantially add to the pool of soil organic matter is debatable. It greatly depends on many factors, especially climatic conditions. General disadvantages of organics are their fertilizer ratios, that are not likely to be matched to plant needs, their nonuniform composition that can prohibit precise uniform applications, and their unpredictable release of nutrients, that may not coincide with the time a particular nutrient is most required by a particular plant. Some organic fertilizers may also contain unwanted, harmful, and=or toxic elements or compounds making them unsatisfactory for utilization. Some may be objectionable due to strong smells or irritants to humans. This latter disadvantage is now important to the quality of life in residential developments near sites of application.
ANIMAL RESIDUES Manures Animal manures were the first fertilizers used in agriculture. Feces and urine from large animals and feces Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001607 Copyright # 2006 by Taylor & Francis. All rights reserved.
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from poultry are the main sources. Most are applied, together with the bedding material, directly to the soil and usually in near proximity to the confined animals. Some is composted and=or pelleted to provide a material that is more agreeable for handling and transport. Nutrient composition can vary widely depending on the animal, its feed, the bedding, and the proportion of manure to bedding, and handling or storage prior to application (Table 1). Because of the importance of animal agriculture, manures will continue to be important sources of fertilizers and pose problems for agriculture and society. As farmers move toward precision applications (that provide improved nutrition without over-application that can result in pollution of soil or water), it becomes increasingly important to analyze manures and apply them in accordance with plant needs. Analyses provided indicate that phosphorus (P) composition is high relative to N for most plant needs. Therefore, application according to N needs provides too much P, that may be bioavailable and add to eutrophication of water via runoff. In some areas with high soil P, the recommendation is to apply manures on the basis of P needs. Such a philosophy will greatly limit applications in fields that are close to confined animals. It will also require N application and possibly other fertilizer nutrients from commercial fertilizers for balanced fertilization of most crops. One attempt to provide more uniform applications and products that are more environmentally friendly to transport is to compost or pelletize manures. Such operations concentrate the manure and reduce transportation costs. Many composting processes have been developed. To date the economics are favorable for some specialty plants but not for broad-scale crop production. Other Animal Residues Bone meal, dried blood, and other animal processing wastes are important fertilizers, but now account for little of the total fertilizer used in the USA. Bone meal is a good source of P, often used by the homeowner but seldom used in commercial agriculture. Dried blood is a rapid releasing organic N source. Other animal
wastes are variable in composition and are often considered as disposal problems rather than desirable fertilizers. Applications may be difficult due to poor and nonuniform physical characteristics. Chemical analysis should be known before application.
PLANT RESIDUES Leaving plant residues on the soil surface provides both nutrients for a following crop and soil protection from wind and rain erosion. Plant residue fertilization may also be obtained from the application of wastes or byproducts from many agricultural processing plants. Trash from cotton gins, filter mud from sugarcane, and processing wastes from fruits and vegetables are but a few of the plant residues utilized. Soil conservationists have long recommended keeping the soil protected by maintaining cover crops during the seasons when the main crops are not planted and returning those plant residues to the soil. The modern emphasis on conservation tillage includes planting directly into cover crops. If the cover crop is a legume, N may be supplied to the planted crop due to the N2-fixation from the legume. A good stand of alfalfa, clover, birdsfoot trefoil or vetch plowed into the soil may replace a fertilizer N application of 80–125 kg N/ha for a following crop of corn.[3,4] Presently, it is believed that such cover crops used in conservation tillage and not incorporated would supply nearly as much N to the following crop.
MUNICIPAL WASTES Sewage treatment plants produce fertilizers in the forms of effluent (the liquid portion) and as biosolids that are settled from the effluent. In some cases, biosolids are placed in a land fill, but costs of maintaining and monitoring see page from landfills is now making the economics favor transportation and land application. Proper handling in the treatment plant removes most human and animal health concerns, but not the stigma of such applications.
Table 1 Concentrations of N, P, and K on a dry-weight basis in commonly applied wastes Waste
N
P
K
References
Livestock manures
1–3%
0.4–2.0%
1–2.5%
[1,2]
Poultry manures
3–5%
1–3%
1–2%
[1,2]
Plant residues
1–7%
0.1–1.7%
0.1–9%
[1]
Municipal biosolids
2–9%
1.5–5%
0.2–0.8%
[9]
Municipal effluents
1.6–2.7 mg=L
0.2–1.2 mg=L
1.1–1.7 mg=L
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[7,8]
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Effluents Ammonium and nitrate-N should be monitored to avoid over-application of effluents, as N leaching can be a problem in sandy soils. When application is made year around, it is necessary to keep the soil covered with an actively growing crop to minimize leaching.[5] Phosphorus fixation capacity of the soil is an important determinant of the amount of effluent that should be applied without promoting a soluble-P problem. High fixing soils will handle greater amounts of P than soils with little fixing capacity.[6] Heavy metals are not a problem as they are concentrated in the solids. Nitrogen, P, and K concentrations of effluents vary quite widely (Table 1).
Biosolids Because of advances in technology, treatment plants are now able to remove nearly all heavy metals and bacteria, allowing the nutrient-rich organic material byproducts or biosolids to be recycled and applied as fertilizer. Elemental concentrations in biosolids from different sources have extremely wide variances (Table 1). They are generally good sources of both N and P for crops, but as for most manures, P application will be too great if enough is applied to satisfy N requirements. Application according to P requirements will allow little or no use in many cases.
OTHER BYPRODUCTS AND WASTES Many other organic byproducts and wastes may be suitable and even valuable as fertilizers. Included would be paper and pulp, vegetable and fruit process byproducts, food wastes, etc.—the list is too extensive to be included here. All wastes should be analyzed for
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nutrient elements and for potential pollutants prior to application.
REFERENCES 1. Huntley, E.E.; Barker, A.V.; Stratton, M.L. Composition and uses of organic fertilizers. In Agricultural Uses of Byproducts and Wastes; Rechcigl, J.E., MacKinnon, H.C., Eds.; American Chemical Society: Washington, DC, 1997; 120–139. 2. Miller, D.M.; Miller, W.P. Land application of wastes. In Handbook of Soil Science; Sumner, M.E., Ed.; CRC Press: Boca Raton, FL, 2000; G-217–G-242. 3. Bruulsema, T.W.; Christie, B.R. Nitrogen contribution to succeeding corn from alfalfa and red clover. Agron. J. 1987, 79, 96–100. 4. Fox, R.H.; Piekielek, W.P. Fertilizer nitrogen equivalence of alfalfa, birdsfoot trefoil, and red clover for succeeding corn crops. J. Prod. Agric. 1988, 1, 313–317. 5. Hook, J.E. Comparison of the crop management strategies developed from studies at Pennsylvania state university. University of Minnesota, and the Muskegon county land treatment system. In Land Treatment of Municipal Wastewater; D’Itri, F., Ed.; Ann Arbor Science: Ann Arbor, MI, 1982; 65–78. 6. Sumner, M.E. Beneficial use of effluents, wastes, and biosolids. Commun. Soil Sci. Plant Anal. 2000, 31 (11–14), 1701–1715. 7. Ellis, B.G.; Erickson, A.E.; Jacobs, L.W.; Knezek, B.D. Crop management studies at the Muskegon county Michigan land treatment system. In Land Treatment of Municipal Wastewater; D’Itri, F., Ed.; Ann. Arbor Science: Ann Arbor, MI, 1982; 49–63. 8. Dowdy, R.H.; Clapp, C.E.; Marten, G.C.; Linden, D.R.; Larsen, W.E. Wastewater crop management studies in Minnesota. In Land Treatment of Municipal Wastewater; D’Itri, F., Ed.; Ann Arbor Science: Ann. Arbor, MI, 1982; 35–47. 9. Forste, J.B. Biosolids processing, products and uses. In Agricultural Uses of Byproducts and Wastes; Rechcigl, J.E., MacKinnon, H.C., Eds.; American Chemical Society: Washington, DC, 1997; 50–62.
Fertilizers: Urban Waste and Sludges Rory O. Maguire North Carolina State University, Raleigh, North Carolina, U.S.A.
James Thomas Sims University of Delaware, Newark, Delaware, U.S.A.
INTRODUCTION Environmental quality is a major issue in many parts of the world and includes important topics such as sustainability and environmental protection. Sustainability and environmental protection often overlap and cover issues such as soil conservation, careful use of finite resources such as inorganic fertilizers, and the responsible recycling of urban wastes and animal manures by agriculture. The beneficial reuse of urban wastes and by-products, e.g., sewage sludge (biosolids), has become an increasingly important issue to attain sustainability as the world’s population increases. This entry describes the uses of urban wastes and biosolids as fertilizers primarily for agricultural settings and the major trends, issues, options, and regulations involved. The main focus is on biosolids, as they constitute the largest portion of urban wastes that are currently land applied.
PRODUCTION OF URBAN WASTES USED AS FERTILIZER Biosolids Production and Quality There are several treatment processes that are routinely carried out in wastewater treatment plants. These determine the quality and properties of the biosolids produced, which in turn affects the options for land application. Following initial screening, wastewater can undergo primary, secondary, and tertiary treatments (Table 1). The treatment used at any particular wastewater treatment plant depends on the effluent discharge limits [e.g., biological oxygen demand (BOD) or nutrient content of the treated wastewater to be discharged into surface waters] and the proposed use for the biosolids and resources available. In addition to these wastewater treatment processes, de-watering of biosolids is frequently used to reduce biosolids volume, which can in turn reduce transportation and disposal costs.
TYPES OF URBAN WASTES THAT ARE USED AS FERTILIZERS
Composting of Biosolids and Municipal Solid Waste
Legislation in most countries requires treatment of wastewater from combined residential, commercial, and industrial sources. Treatment of wastewater produces a semisolid by-product that is commonly known as ‘‘sewage sludge’’ or ‘‘biosolids.’’ There are several disposal pathways for biosolids including incineration, landfilling, and application to land as a fertilizer. Use of biosolids in agriculture is a well-established and regulated process in many parts of the world, including U.S.A. and Europe. To a lesser extent, other urban and industrial by-products, e.g., paper waste, and municipal solid waste (MSW), such as leaves, grass clippings, or other organic materials, is also applied to agricultural land, often following composting. Sometimes biosolids can be cocomposted with industrial by-products or MSW.
Composting (often called cocomposting when two or more materials are composted together) is the decomposition of organic matter by micro-organisms in a controlled environment that has optimum moisture and oxygen contents. The increase in temperature during composting can destroy most pathogens. Composting of biosolids or the organic fraction of MSW may cause offensive odors and odor control systems, such as scrubbers and biofilters, are usually required in populated areas. Composting of biosolids involves mixing de-watered biosolids with a bulking agent, such as MSW, wood chips, or straw, followed by aerobic decomposition. Only a small proportion of biosolids and MSW are composted worldwide, but in certain areas composting accounts for a large proportion of the urban wastes generated. For example, Edmonton, Canada, is able to
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042690 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
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Table 1 Wastewater treatment processes Treatment name
Treatment process
Screening and grit removal
Generally a combination of sedimentation and passing through a large screen to remove stones, grit, and any large debris, such as branches, that may have entered the sewage system. The product of this process is nearly always regarded as a solid waste rather than biosolids and is usually landfilled
Primary
Follows screening and grit removal and usually involves sedimentation to remove suspended solids prior to secondary treatment
Secondary
Normally a biological treatment in which micro-organisms are used to reduce suspended solids and BOD, thereby eliminating fish kills when the wastewater is discharged. This is the minimum wastewater treatment process required in the U.S.A.
Tertiary
Used where higher standards are required for effluent quality or to improve biosolids quality for land application. Examples include addition of lime for pathogen and odor control, iron or aluminium salts for precipitation of P, and polymers for removal of suspended sediments
divert 70% of its residential waste from landfill using recycling and cocomposting.[1] Where the organic fraction of MSW is composted, it can either be source separated by the resident or screened and separated from regular residential garbage, and composted alone or mixed with biosolids before being composted.
REGULATIONS COVERING LAND APPLICATION OF URBAN WASTES Land application of biosolids normally depends on the wastewater treatment process used to produce the biosolids. As specific rules vary between countries, it is impossible to describe about all of them in this entry.[2,3] However, it is possible to make some generalizations about land application of biosolids. For example, secondary and=or tertiary treatment, mainly to control pathogens and odors, is normally required before land application is permitted. In U.S.A., biosolids applications are governed by Title 40 of the Code of Federal Regulations, Part 503,
commonly referred to as the ‘‘503 rule,’’ which sets limits for toxic metals in biosolids, and for both annual and cumulative loadings to land (Table 2). Limits for chromium and molybdenum are currently under consideration. The 503 rule also classifies biosolids as either ‘‘Class A’’ or ‘‘Class B’’ for pathogen control. The content of polychlorinated biphenyls in biosolids to be land applied is limited to a maximum of 50 mg=kg, under Title 40 of the Code of Federal Regulations, Part 761. Similar rules are in effect in the European Community, under Council Directive 86=278=EEC, implemented in 1986 and currently under revision.
AGRICULTURAL MANAGEMENT OF URBAN WASTES AS FERTILIZERS The benefits of biosolids and compost applications to soil quality are many and well documented. Biosolids and composts are good sources of nitrogen (N), phosphorus (P), and potassium (K). Typical biosolids
Table 2 Pollutant limits set by the 503 rule for toxic metals in biosolids applications to land
Pollutant Arsenic Cadmium
Ceiling concentration limits for all biosolids applied to landa (mg/kg)
Cumulative pollutant loading rate limits (kg/ha)
75
Annual pollutant loading rate limits (kg/ha/yr)
41
2
85
39
1.9
4300
1500
75
840
300
15
57
17
0.85
Nickel
420
420
21
Selenium
100
100
5
7500
2800
140
Copper Lead Mercury
Zinc a
Maximum concentration of pollutant permitted in any biosolids to be land applied.
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contain 4.0%, 2.0%, and 0.4% of N, P, and K, respectively, on a dry weight basis, while the equivalent values for MSWs are 0.7%, 0.2,% and 0.3%, respectively. Composted biosolids contain less total N than uncomposted biosolids, owing to the addition of other materials to aid composting and loss of ammonia during the composting process. The N in composted biosolids is released more slowly, which decreases nitrate leaching. Thus, the N is available to plants over a longer period, which is more consistent with crop N uptake patterns.[2] Biosolids and composts can also be good sources of Ca, Mg, and S, and of the micronutrients Fe, Cu, B, Zn, Mn, and Mo. Biosolids and composts can promote beneficial microbial activity and diversity that suppress plant diseases and the need for costly pesticides. Biosolids and composts can also improve water infiltration, water retention, and soil structure, which in turn increases resistance to wind and water erosion. In U.S.A., in 1998, land application of biosolids accounted for 41% of the total produced, while advanced treatments such as composting accounted for 12%.[2] The annual production of biosolids (7 million Mg=yr) is small in comparison to animal manure production (174 million Mg=yr) in U.S.A. However, the land application of biosolids constitutes a significant economic saving for many biosolids producers and saves landfill space, which is an increasingly expensive, finite resource in many areas.
POTENTIAL PROBLEMS ASSOCIATED WITH LAND APPLICATION OF BIOSOLIDS Legitimate concerns about the need to prevent toxic metals and pathogens from affecting human and ecosystem health have been addressed through regulation and record keeping of applications of biosolids to land. However, there is currently a debate as to whether the limits set for toxic metals and pathogens are strict enough. Some scientists think that metal bioavailability will increase as the organic matter added with the biosolids is mineralized, while others argue that the evidence to support this hypothesis is inconclusive. Biosolids and composts have a low N : P ratio compared to crop requirements. Biosolids applications are generally carried out according to N-based nutrient management plans that over-apply P, and can lead to a buildup of P in agricultural soils.[4] Buildup of soil P in many areas has been linked to increase in losses of P from agriculture to surface waters, with a corresponding decrease in water quality. In the future, biosolids may have to be applied according to P-based nutrient
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management plans. This will decrease the amount of biosolids that can be applied per unit area of land, introduce the necessity for inorganic N fertilizers, and increase other associated costs. Nuisance issues such as odors and attraction of pests are of public concern when application sites are close to residential areas.[5]
CONCLUSIONS Efforts to recycle municipal wastes will likely continue, driven by human population growth, the continuing rise in cost of landfill, and the goal of sustainability in agriculture and the environment as a whole. However, the future of land-application programs for biosolids is uncertain. For example, the USEPA has forecast an increase in the beneficial use of biosolids in land-application programs because of increasing costs associated with landfill, and an increase in biosolids quality owing to stricter regulations covering biosolids production. Despite increasing biosolids quality, the argument over the long-term environmental impact of pollutants in biosolids will likely continue. Further regulation of the application of P to agricultural land may also increase costs associated with land-application programs for biosolids and municipal wastes. However, if the potential negative side effects associated with the land application of biosolids and composted waste are properly managed, then the beneficial use of these by-products will continue.
REFERENCES 1. www.gov.edmonton.ab.ca (accessed May 2001). 2. U.S. Environmental Protection Agency. In Biosolids Generation, Use, and Disposal in the United States, EPA530-R-99-009; September 1999. 3. Commission of the European Communities. Council directive on the protection of the environment, and in particular soil, when sewage sludge is used in agriculture (86=278=EEC). Official Journal of the European Communities 1986, No. 2, 181=6–12. 4. Maguire, R.O.; Sims, J.T.; Coale, F.J. Phosphorus solubility in biosolids-amended farm soils in the mid-atlantic region of the U.S. J. Environ. Qual. 2000, 29 (4), 1225–1233. 5. Sims, J.T.; Pierzynski, G.M. Assessing the impacts of agricultural, municipal, and industrial by-products on soil quality. In Land Application of Agricultural, Industrial, and Municipal By-Products; Power, J.F., Warren, A.D., Eds.; Soil Sci. Soc. Am.: Madison, WI, 2000; 237–261.
Fire and Soils P. K. Khanna Institute of Silviculture, University of Freiburg, Freiburg, Germany
R. J. Raison CSIRO Forestry and Forest Products, Kingston, Australian Capital Territory, Australia
INTRODUCTION
ATMOSPHERIC LOSSES OF ELEMENTS
Fires have played an integral role in the evolution and ecology of many ecosystems of the world. Natural and managed fires burn extensive areas annually,[1] and shape the landscape through effects on vegetation, soil, water, biodiversity, and socioeconomics. Fire has been actively managed for human benefit for millennia. In the tropics, slash-and-burn agriculture uses fire to release many of the nutrients accumulated in vegetation during a fallow period. Similarly, fire is widely used to remove forest and agricultural residues prior to establishment of a new crop and to enhance grazing. Fire is a dominant driver of the historical and current vegetation dynamics in forests, woodlands, shrublands, and grasslands in many parts of the world. Fire management practices (suppression, prescribed burning, etc.) remain controversial in many parts of the world because they can affect soil and a range of other factors with environmental values, including GHG emissions (CO2, CO, CH4, and NO2) and air quality.
During vegetation fires, atmospheric losses of elements occur in nonparticulate (e.g., C, N, S, and P) and particulate forms (Ca, Mg, K, and P), and postfire residues (partially burnt fuels, ash, and char components) are deposited on the soil. Depending upon the degree of combustion, a range of GHG gases are formed, the most important ones being CO2, CO, N2O, and CH4. Elements undergoing nonparticulate (gaseous) losses would undergo a long-range transport in the atmosphere (considered to be a complete loss to ecosystems), whereas particulates may be carried for only shorter distances. Raison et al.[4] used the conservation of Ca to distinguish between particulate and nonparticulate losses of different elements, and reported that a direct correlation between loss of N and loss of mass of plant material existed, providing the possibility of estimating accurately the loss of N from N content of the fuel and the amount of dry matter burnt. Up to 60% of P contained in the fuel may be lost, depending on factors such as the temperature, forms of P in the fuel, cation content of the ash, and the amount of ash transport. The nonparticulate transfer of P may range from 30% (low combustion) to 50% (high combustion). When combustion is relatively complete (gray ash is produced), nonparticulate losses of many elements may account for 60–80% of the total atmospheric transfer.[4]
FIRE CATEGORIES AND FIRE IMPACTS ON SOILS Fire can affect soil properties and processes both directly, as a result of combustion (via nutrient transfers to the atmosphere, ash, and char inputs, soil heating), and subsequently, as a result of a myriad of changes to ecosystem processes such as changed mineralization rates of soil organic matter and litter, erosion of ash and nutrient-rich surface soil, vegetation succession, and changes to N-fixing systems.[2] The scale of change ranges from minutes (soil heating) to many decades (vegetation succession), with the postfire impacts on soils often being the most dominant. Intensity and frequency of fires are major factors affecting the change in soils. The type and quantity of fuel consumed, and thus the duration of soil heating can be used to categorize fires in terms of impacts on soil and ecosystem processes (Table 1) 708 Copyright © 2006 by Taylor & Francis
EFFECTS OF SOIL HEATING Less than 10% of the heat produced during a vegetation fire is radiated downward, yet this heating is responsible for much of the direct changes in soil properties caused by forest fire.[5] The direct effects of heating on organic matter and soils range from mild sterilization and denaturing of protein at 50–60 C, to changes to clay minerals at 950 C.[3] Depending upon the degree of oxidation, carbonized products are produced, which range from mineral gray ash containing Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120025110 Copyright # 2006 by Taylor & Francis. All rights reserved.
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Table 1 Fire categories as defined by fuel type, fuel quantity, and the duration of soil heating
Fire category
Fuel types
Fuel consumption (t/ha)
Maximum temperature ( C) at 2-cm depth
Time (hr) for which soil is heated above 80% of the maximum temperature
Frequency of occurrence (yr)
Relative impact on soils
Windrows
Mostly trunks and slash
100–400þ
500
>24
30–100þ
High
Forest regeneration=slash
Tree crowns, some logs, shrubs, and litter
50–300þ
200
0.5–2
30–100þ
High
Forest wildfire
Litter, shrubs, and crowns
20–60
100
0.1–1
20–100þ
Medium–high
Shrubland
Litter and crowns
15–30
80
0.1–0.5
20þ
Medium–low
Grassland, crop residue
Litter, crop residues
0.5–5.0
60
0.1–0.3
1þ
Low
Values are a guide, with considerable variation observed. (From Ref.[3].)
very little residual C to black residue with a high amount of C and charred substances. Moderate heating can render soil organic matter more prone to microbial respiration under postfire conditions.[3] Soil heating may be as important as the addition of ash in slash-and-burn systems, and can increase mineral N and P fractions.[6]
EFFECTS OF ASH ADDITIONS After fire, postfire residues deposit highly aromatic (char) carbon. About 1–5% of burnt fuel is converted to char, and this is considered to be relatively inert and likely to be long-lived in soils[7] and sediments. Elements, except C and N, are enriched when ash is formed, and the level of their enrichment depends on the degree of combustion and initial fuel characteristics. In comparison with unburnt eucalypt fuels, concentrations of Ca, Mg, and P increased by 10- to 50-fold, 10- to 35-fold, and 10-fold, respectively,[8] with high values in gray ash. As ash is prone to be transported by wind and water, any loss of ash can cause major losses of elements from ecosystems. Ash is highly alkaline and will increase the pH of the soil and its capacity to buffer protons. The salt content of ash may initially inhibit seedling growth, but plants growing around an ashbed benefit from the nutrients made available in the short- and long term, causing the so-called ‘‘ashbed effect.’’ Ash can also stimulate the soil biological activity[9] and interact positively with the effects of soil heating.[10]
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CHANGES IN SOIL PHYSICAL PROCESSES Fire affects water penetration and erosion susceptibility, by creating hydrophobicity[11] in the surface soil. Erosion has major effects on soil fertility. Blackening of the soil surface and removal of vegetation and litter can increase soil temperature. Where fire reduces the vegetation cover, frost damage may increase, plant water uptake is reduced, thereby increasing the soil wetness, and, sometimes, rates of mineralization of soil organic matter and leaching of nutrients.
CHANGES IN SOIL CHEMICAL PROPERTIES AND PROCESSES Large quantities of cations (Ca, Mg, K, and NH4) and anions (Cl and SO4) and soluble silica are mobilized in surface soils by vegetation fire, especially under ashbeds[12] where Ca remained the main cation in the solution phase of surface soil during a three-year study period. Increase in exchange capacity (because of the pH change in acid soils) and the exchangeable base cations occurs after fire and may remain so for many years after intense fire. Nitrification rates and hence the potential for leaching of nitrate and cations may be increased after intense fire.[2] A small fraction (about 10%) of total P in ash may be soluble in water.[9] Protons are needed to mobilize P deposited in ash and, therefore, mixing of ash with acid soil is required before P can be used by postburn vegetation. The P-sorption capacity of soils usually increases after intense forest fire.
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CHANGES IN BIOLOGICAL PROPERTIES OF SOILS The effects of fire on biological processes are complex and can be very site dependent. Fire often enhances the decomposition of organic matter and the mineralization of organically bound elements. This can be because of the changed microbial populations, altered substrate quality (additional soluble C), and more favorable environmental factors (temperature, moisture, and pH). For example, in laboratory experiments where ash was added to different soils, enhanced respiration rates, especially in soils with high organic matter content, were observed during 6 weeks of incubation[9] until the easily mineralizable soil C was respired.[13] Nitrogen mineralization rates and the amount of nitrate produced usually increase following a fire, and in some cases may even lead to denitrification losses.[9] A change in microbial population (autotrophic nitrifiers replacing heterotrophic nitrifiers) after fire has been proposed by Bauhus, Khanna, and Raison.[13] Study of denitrification rates after fire deserves greater research attention. MANAGEMENT OF SOILS FOLLOWING FIRE One of the immediate concerns following vegetation fires is to minimize soil erosion and to replenish nutrients that are lost by atmospheric transfer or erosion. Losses of N can be large (several hundred kg=ha) in forests that are subjected to wildfires or slash burns. In natural systems, given sufficient time, N-fixing processes can maintain N balance. Replenishment of lost P and cations may take decades or centuries, which may affect plant productivity if such fires occur frequently. In managed systems, fertilizer inputs may be needed to maintain productivity. REFERENCES 1. UNEP. Wild Fires, a Double Impact on the Planet, 2005. http:==www.grid.unep.ch=product=publication= earlywarning.php.
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Fire and Soils
2. Raison, R.J.; O’Connell, A.M.; Khanna, P.K.; Keith, H. Effects of repeated fires on nitrogen and phosphorus budgets and cycling processes in forest ecosystems. In Fire in Mediterranean Ecosystems, Report No. 5, Ecosystem Research Series; Trabaud, L., Prodon, R., Eds.; Commission of the European Communities: Brussels, 1993; 347–363. 3. Walker, J.; Raison, R.J.; Khanna, P.K. Fire. In Australian Soils—The Human Impact; Russell, J.S., Isbell, R.F., Eds.; Queensland University Press: Brisbane, 1986; 186–216. 4. Raison, R.J.; Khanna, P.K.; Woods, P.V. Mechanisms of element transfer to the atmosphere during vegetation fires. Can. J. For. Res. 1985, 15, 132–140. 5. Neary, D.G.; Klopatek, C.C.; DeBano, L.F.; Folliott, P.F. Fire effects on belowground sustainability: a review and synthesis. For. Ecol. Manage. 1999, 122, 51–71. 6. Giardina, C.P.; Sanford, R.L.; Dockersmith, I.C. Changes in soil phosphorus and nitrogen during slashand-burn clearing of a dry tropical forests. Soil Sci. Soc. Am. J. 2000, 64, 399–405. 7. Skjemstad, J.O.; Taylor, J.A.; Smernik, R.J. Estimation of charcoal (char) in soil. Commun. Soil Sci. Plant Annal. 1999, 30, 2283–2298. 8. Raison, R.J.; Khanna, P.K.; Woods, P.V. Transfer of elements to the atmosphere during low-intensity prescribed fires in three Australian subalpine eucalypt forests. Can. J. For. Res. 1985, 15, 657–664. 9. Khanna, P.K.; Raison, R.J.; Falkiner, R.A. Chemical properties of ash components derived from Eucalyptus litter and its effects on forest soils. For. Ecol. Manage. 1994, 66, 107–125. 10. Raison, R.J. Modification of the soil environment by vegetation fires, with particular reference to nitrogen transformations: a review. Plant Soil 1979, 51, 73–108. 11. DeBano, L.F.; Neary, D.G.; Folliott, P.F. Fire’s Effects on Ecosystems; John Wiley & Sons: New York, U.S.A., 1998. 12. Khanna, P.K.; Raison, R.J. Effects of fire intensity on solution chemistry of surface soil under a Eucalyptus pauciflora forest. Aust. J. Soil Res. 1986, 24, 423–434. 13. Bauhus, J.; Khanna, P.K.; Raison, R.J. The effect of fire on carbon and nitrogen mineralization and nitrification in an Australian forest soil. Aust. J. Soil Res. 1993, 31, 621–639.
Flooding Tolerance of Crops Tara T. VanToai Getachew Boru Jianhuan Zhang United States Department of Agriculture (USDA), The Ohio State University, Columbus, Ohio, U.S.A.
INTRODUCTION Periodic flooding during the growing season adversely affects crop growth and productivity, with the exception of flooded rice, in many areas of the U.S. and the rest of the world. Soil can become flooded when it is poorly drained or when rainfall or irrigation is excessive. Other terms, such as soil saturation, waterlogging, anoxia, and hypoxia, are also commonly used to describe flooding conditions. Flooding causes premature senescence, which results in leaf chlorosis, necrosis, defoliation, reduced nitrogen fixation, cessation of growth, and reduced yield. The severity of the flooding stress is affected by many factors, including flooding duration, crop variety, growth stage, soil type, fertility levels, pathogens, and flooding conditions.[1] In general, stream flooding, characterized by the overflow of rivers or creeks into a flood plain, is more damaging than lowland flooding, characterized by inadequate surface drainage and slow soil permeability of depressional areas. Sediments carried by stream flooding, when deposited on the leaves of flooded plants, can cause severe wilting and plant death within 24 hr of the stress. Flooding can be further divided into either waterlogging, where only the roots are flooded, or complete submergence, where the entire plants are under water. While plants develop adaptive mechanisms to allow them to survive long-term waterlogging, most plants die within one or two days of submergence.[1] The lack of oxygen has been proposed as the main problem associated with flooding.[2] Indeed, tolerance of anoxia and hypoxia has been used synonymously with tolerance of flooding stress. During the last two decades, a great deal more information has accumulated from research on the molecular, biochemical, and physiological responses of plants to the lack of oxygen rather than to flooding per se.[3–5] However, tolerance of field flooding appears to be much more complex than tolerance of artificially induced hypoxia and anoxia. Contrary to the injury seen in flooded fields, soybeans can thrive in stagnant water in the greenhouse and soybeans grown in hydroponic medium continuously bubbled with nitrogen gas, where the dissolved oxygen level was not detectable, showed no symptoms of stress.[6] Soybean, therefore, is much Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001680 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
more tolerant to excessive water and a lack of oxygen than previously expected. The reasons underlying the dramatic differences between responses to flooding in the greenhouse and flooding in the field are not known. However, growth reduction and yield loss in flooded fields could arise from root rot diseases, nitrogen deficiency, nutrient imbalance, and=or the accumulation of toxic levels of CO2 in the root zone. Indeed, the levels of CO2 commonly found in flooded soil (30%) severely caused leaf chlorosis and reduced plant biomass of soybean, a flood-susceptible crop, but not of rice, a flooding-tolerant crop (VanToai, unreported data).
MORPHOLOGICAL AND ANATOMICAL ADAPTATION TO FLOODING STRESS One important morphological change associated with flooded roots is the formation of aerenchyma tissue, which contains continuous gas-filled channels connecting the root with the shoot. Other morphological changes, including hypertrophy and the formation of lenticels, adventitious roots, and pneumatophores, have also been observed in many plant species.[7] Flooding can also change the direction of root growth. Roots of tomato and sunflower plants become disgeotropic or negatively geotropic under flooding conditions instead of positively geotropic.[7] The changes in orientation of roots under flooding conditions enables them to escape stress from the reduced oxygen availability by growing closer to the better aerated soil surface.
PHYSIOLOGICAL, BIOCHEMICAL, AND MOLECULAR ADAPTATION TO FLOODING STRESS Rice cultivars that showed rapid leaf and sheath growth during submergence did not survive as well as cultivars that did not elongate. Tolerant cultivars appeared to conserve carbohydrates in the shoots and roots during submergence.[8] Upon removal of the stress, tolerant rice cultivars are able to recover more rapidly and suffer less plant mortality.[9] An adequate 711
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supply of sugar is needed for corn root tips to survive anoxic and hypoxic stresses.[10] The lack of oxygen induces a set of anaerobic proteins in roots to allow plants to cope with the stress.[11] These stress proteins are enzymes of either glycolysis, glucose metabolism, or fermentation.[10,12]
GENETIC VARIABILITY IN FLOODING TOLERANCE Flooding tolerance is usually defined as minimal or no yield loss. According to VanToai et al.,[13] waterlogging for four weeks during the early flowering stage reduced the average grain yield of 84 U.S. soybean cultivars by 25%. Yield reduction, however, varied from 9% in the most flooding tolerant cultivar to 75% in the most flooding susceptible cultivar. Flooding tolerance can also be defined as high yield under flooding stress. According to this definition, the most flooding tolerant variety in this study produced 3.7 Mg ha1, while the least produced 1.27 Mg ha1. When the cultivars were ranked for flooding tolerance based on both definitions, seven of the ten most flooding tolerant cultivars were the same; and seven of the ten least flooding tolerant cultivars were also the same. Thus, the two definitions of flooding tolerance, either high yield under flooding or minimal yield difference between nonflooded and flooded conditions, appear to be compatible. Flooding tolerance is independent from nonflooded yield indicating that genetic variability for flooding tolerance exists and could be improved through plant breeding and selection. Studies of submergence tolerance of rice showed that the unimproved land races FR13A, Janki, and FR43B had survival values ranging from 41 to 51% after 10 days of submergence, while only 2–4% of elite cultivars (IR74, IR48 and IR68) survived.[9]
IMPROVING FLOODING TOLERANCE BY TRADITIONAL PLANT BREEDING Tolerance of flooding in wheat (Triticum aestivum L.) and rice (Oryza sativa L.) is a quantitative trait controlled by a small number of genes.[9,14] Using the submergence tolerant land races FR13A, Janki, and FR43B as donor parents, rice breeders at the International Rice Research Institute (IRRI) at Los Banos in the Philippines have developed an experimental rice line (IR49830-7-1-2-2) from crosses with the short stature, high-yield IR lines, which produced as much as 4880 kg ha1.[9] The result showed that submergence tolerance can be incorporated into improved, highyielding cultivars to raise the productivity in submergence-prone areas.
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Flooding Tolerance of Crops
IDENTIFYING FLOODING TOLERANCE LOCI AND IMPROVING FLOODING TOLERANCE BY MOLECULAR PLANT BREEDING Xu and Mackill[15] identified a single submergence tolerance locus, Sub1, that controls about 50% of the variation in submergence tolerance of rice. During the last few years, molecular marker aided selection has been used successfully for the breeding of crops with improved quantitative traits. VanToai et al.[16] identified a single DNA marker that was associated with improved plant growth (from 11 to 18%) and grain yields (from 47 to 180%) of soybean in waterlogged environments. The identified marker was uniquely associated with waterlogging tolerance and wasnot associated with maturity, normal plant height or grain yield. Near isogenic lines with and without the flooding tolerant marker have been developed and are being field tested under waterlogging conditions to confirm the association of the marker with the tolerance of soybean to waterlogging stress.
IMPROVING FLOODING TOLERANCE BY GENETIC TRANSFORMATION Flooding induces or accelerates plant senescence in tobacco, tomato, sunflower, carrot, barley, peas, wheat, maize, and soybean. The most obvious visual symptom of flooded plants under stress is the yellowing of leaves followed by necrosis due to premature senescence. Within one day of flooding, the concentration of the antiaging hormone, cytokinin, in sunflower xylem sap declined sharply to a very low level.[17] In order to test if enhanced endogenous cytokinin production could improve flooding tolerance, Zhang et al.[18] generated transgenic plants containing a gene coding for cytokinin biosynthesis. Four transgenic Arabidopsis lines were chosen for cytokinin and flooding tolerance determinations. The levels of cytokinin were similar between wild-type and transgenic plants in the unflooded treatment. After 5 days of waterlogging, the cytokinin increased 3–10 times in transgenic plants as compared to wild-type plants. In three independent experiments, all four transgenic lines were consistently more tolerant to soil waterlogging and complete submergence than wild-type plants. The results indicated that endogenously produced cytokinin can regulate senescence caused by flooding stress, thereby increasing plant tolerance of flooding. This study provides a novel mechanism to improve flooding tolerance in plants.[18] In summary, while the lack of oxygen has been used interchangeably with flooding stress, tolerance of field flooding is more complex than tolerance of anoxia and hypoxia. The use of molecular plant breeding
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and genomic transformation to improve flooding tolerance in crops is promising to be successful.
REFERENCES 1. Sullivan, M.; VanToai, T.; Fausey, N.; Beuerlein, J.; Parkinson, R.; Soboyejo, A. Evaluating on-farm flooding impacts on soybean. Crop Science 2001, 41, 1–8. 2. Kozlowski, T.T. Extent, causes, and impacts of flooding. In Flooding and Plant Growth; Kozlowski, T.T., Ed.; Academic Press Inc.: Orlando, FL, 1984; 1–7. 3. Kennedy, R.A.; Rumpho, M.E.; Fox, T.C. Anaerobic metabolism in plants. Plant Physiology 1992, 84, 1204–1209. 4. Perata, V.M.; Alpi, A. Plant responses to anaerobiosis. Plant Science 1993, 93, 1–17. 5. Ricard, B.; Couee, I.; Raymond, P.; Saglio, P.H.; Saint-Ges, V.; Pradet, A. Plant metabolism under hypoxia and anoxia. Plant Biochemistry 1994, 32, 1–10. 6. Boru, G.; VanToai, T.; Alves, J.D. Flooding injuries in soybean are caused by elevated carbon dioxide levels in the root zone. Fifth National Symposium on Stand Establishment 1997, 205–209. 7. Hook, D.D. Adaptations to flooding with fresh water. In Flooding and Plant Growth; Kolowski, T.T., Ed.; Academic Press: Orlando, FL, 1984; 265–294. 8. Jackson, M.B.; Waters, I.; Setter, T.; Greenway, H. Injury to rice plants caused by complete submergence: a contribution by ethylene (ethene). Journal of Experimental Botany 1987, 38, 1826–1838.
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9. Mackill, D.J.; Amante, M.M.; Vergara, B.S.; Sarkarung, S. Improved semidwarf rice lines with tolerance to submergence of seedlings. Crop Science 1993, 33, 749–753. 10. Ricard, B.; Saglio, P.; VanToai, T.; Chourey, P. Evidence for the critical role of sucrose synthase for anoxic tolerance of maize roots using a double mutant. Plant Physiology 1998, 116, 1323–1331. 11. Sachs, M.M.; Freeling, M.; Okimoto, R. The anaerobic proteins of maize. Cell 1980, 20, 761–767. 12. Sachs, M.M.; Subbaiah, C.C.; Sabb, I.N. Anaerobic gene expression and flooding tolerance in maize. Journal of Experimental Botany 1996, 47, 1–15. 13. VanToai, T.; Beuerlein, J.E.; Schmitthenner, A.F.; St. Martin, S.K. Genetic variability for flooding tolerance in soybeans. Crop Science 1994, 34, 1112–1115. 14. Boru, G.; Ginkel, V.M.; Kronstad, W.E.; Boersma, L. Expression and inheritance of tolerance to waterlogging stress in wheat. Euphytica 2001, 117, 91–98. 15. Xu, K.; Mackill, D.J. A major locus for submergence tolerance mapped on rice chromosome 9. Molecular Breeding 1996, 2, 219–224. 16. VanToai, T.T.; St. Martin, S.K.; Chase, K.; Boru, G.; Schnipke, V.; Schmitthenner, A.F.; Lark, K.G. Identification of a QTL associated with tolerance of soybean to soil waterlogging. Crop Science 2001, 41, 1247–1252. 17. Burrows, W.J.; Carr, D.J. Effects of flooding the root system of sunflower plants on the cytokinin content of the xylem sap. Physiol Plant. 1969, 22, 1105–1112. 18. Zhang, J.; VanToai, T.; Huynh, L.; Preiszner, J. Development of flooding-tolerant Arabidopsis Thaliana by autoregulated cytokinin production. Molecular Breeding 2000, 6, 135–144.
Fluid Flow: Challenges Modeling John L. Nieber University of Minnesota, St. Paul, Minnesota, U.S.A.
INTRODUCTION The unsaturated zone (vadose zone) of the Earth’s crust is an important interface for both the underlying groundwater and the overlying surface water resources and atmosphere. Quantifying fluid flow, mass transport, and energy transport processes in the unsaturated zone have become a focus for researchers, government agencies, and consultants during the past three decades because it is found that the outcome of these processes have an impact on the sustainability of modern social structures. While sophisticated sensors and instrumentation seems to have been developed to provide data from the field on a real-time basis, these cannot be used to directly predict the possible outcomes. Instead, this prediction requires the use of mathematical models representing the flow and transport processes. The following describes some of the applications of models for flow in the unsaturated zone, past challenges and achievements in improving modeling methods, and future challenges to modeling flow.
APPLICATION OF MODELS Models for simulating flow processes in soil and groundwater find applications in many environmentally oriented disciplines including geography, soil science, agricultural engineering, civil engineering, geoengineering, hydrogeology, and meteorology. These models are generally based on numerical solutions of governing equations and require the use of digital computers to complete the calculation task. There are many current and potential applications for such models, but a short list of the common applications includes: 1) estimation of groundwater recharge volume and contaminant loading; 2) design of measures to remediate contaminated soils and groundwater; 3) design of efficient drainage and irrigation systems for efficient crop production; 4) estimation of runoff production from land in response to rainfall and/or snowmelt; and 5) assessment of the impact of global climate change on surface and subsurface water resources. 714 Copyright © 2006 by Taylor & Francis
Models developed for these applications need to satisfy two criteria to be put to use by a practitioner. They have to be fairly easy to use and dependable. The first criterion, ease-of-use, only requires a good team of programmers, and does not pose a challenge for flow modeling. The second criterion stipulates that the model provides accurate results in a timely manner. This is a direct challenge to flow modeling. The following sections present information on the past and future challenges associated with the development of dependable models.
PAST CHALLENGES AND ACHIEVEMENTS During the past three decades there has been substantial progress in the development of numerical models for simulating relevant unsaturated zone processes. During this time predominant attention in modeling flow processes was given to the Richards equation.[1] In the past, many of the difficulties in model development involved the determination of the best ways to solve this equation. Due to the highly nonlinear character of the Richards equation, analytical solutions [2] to the equation were possible only for simplified conditions, and therefore numerical solution methods were necessary to treat realistic field conditions. Numerical methods such as the finite difference method and the finite element method were adopted from other engineering and science applications and applied to discretize the Richards equation into systems of nonlinear algebraic equations. Two major numerical solution problems were faced by researchers in solving this equation. One was the highly nonlinear nature of the equation and associated boundary conditions, leading to problems of slow convergence or even nonconvergence of the solution methods. This problem was handled by applying nonlinear equation solvers classified within the broad class of Newton methods and Picard methods.[3] A second problem was the need to be able to solve large systems of algebraic equations, which in earlier years involved hundreds or perhaps thousands of equations. Due to the relatively small memory Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001757 Copyright # 2006 by Taylor & Francis. All rights reserved.
Fluid Flow: Challenges Modeling
available on early computers it was necessary to use iterative methods to solve even moderate-sized problems. Conventional iterative methods like Jacobi, Gauss–Seidel, and successive over-relaxation methods[4] were used to solve these problems. While these methods were satisfactory for relatively homogeneous systems, for strongly heterogeneous systems it was found that these methods led to poor convergence or even nonconvergence. Computer memory did increase substantially during the 1980s and 1990s, and this allowed the use of direct equation solvers for the types of problems solved in the earlier years. However, with the increase of computer memory storage, the problems tackled have also increased memory requirements (tens of thousands to millions of equations need to be solved) and iterative methods are once again back in vogue. Fortunately, the efficiency of iterative methods has also increased substantially with the development of conjugate gradient methods[5] and multigrid methods.[6] During the last 30 years there has been an ongoing effort to find the recipe for a numerical method or set of methods that will be robust for solving the Richards equation.[3,4,7–12] The desire has been to develop computationally efficient methods applicable to a broad range of practical problems, especially for large-scale, three-dimensional, heterogeneous flow systems. Associated problems involved assuring that the solutions were mass conservative and that the iterative methods used to solve the nonlinear algebraic equations would converge even for conditions where the soil is very dry and highly heterogeneous. Detailed analysis of how to assure a mass conservative solution has been given in Ref.[8]. Assurance of nonlinear iteration convergence has been found to be more problematic and recent improvements have been made using techniques involving primary variable switching,[9,10] higher order time integration,[11] and variable transformation.[12] Aside from the obvious problems associated with solving the Richards equation there has been the need to assign (spatially) the equation parameters for field scale applications of the numerical solutions. For instance, the catchment scale model of Ref.[13], like the model of Ref.[4], was developed to facilitate the simulation of three-dimensional variably saturated flow over an entire catchment. While the solution of the large system of algebraic equations for such a problem offers a significant challenge to modeling, an equally if not larger challenge is the problem of assigning parameters to the cells in the numerical grid. The problem of parameter assignment is two-fold. For one, there is the problem of determining the spatial distribution of the parameters at the scale of the numerical grid cell. Involved with this problem is the uncertainty in predicting these values, given limited field data. Geostatistical methods[14] were developed
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to facilitate such prediction and to estimate limits of uncertainty. A second problem arises because small scale features, and even small scale processes, occurring below the sampling scale of the field scale grid cell can significantly influence the actual outcome at the field scale, but are not directly predictable by the governing equation(s) discretized at the field scale grid. There has been some success[15] in developing techniques that provide parameters that account for these subgrid scale features and processes. These parameters, called effective parameters, are those that yield effectively the same outcome as would occur if the more detailed parameter distribution were used.
FUTURE CHALLENGES TO MODELING Two of the greatest future challenges to modeling include the need to more completely describe the flow and transport processes, and the need to incorporate multiscale phenomena into the modeling analysis. The first challenge involves the expansion of the governing equations to include coupled physical and chemical processes. The second challenge involves the assignment of equation parameters and the incorporation of subgrid features and processes. To assure the success of future modeling, this second challenge is the most critical to address.
Governing Equations As awareness of environmental problems has increased, and environmental regulations have become more stringent, the scope for modeling has expanded from modeling the flow of water alone to modeling coupled multiphase fluid flows, mass (solute) transport and energy (thermal) transport. The coupled equations for isothermal multiphase fluid flow have been reviewed in detail.[16] Numerical solutions of coupled two-phase flow equations for applications to environmental problems have advanced considerably in the last 20 years. One of the earlier multiphase flow solutions is given in Ref.[17], while methods representing the latest advances in computational efficiency are given in Ref.[18]. Equations for nonisothermal conditions, which until recently have received much less attention, have been presented in Ref.[19]. Solutions of these equations offer new challenges to those developing numerical solutions.[20,21] Recent techniques such as those mentioned before for the solution of the Richards equation and the coupled multiphase flow equations
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should be tested to improve the efficiency of such solutions.
Process Scale Numerical solutions of flow and transport processes for field-scale applications are generally performed on relatively large numerical grids. The reason for this is two-fold. First, the computational effort to simulate field-scale problems can easily exceed the capabilities of today’s computers (using current numerical methods) if too fine a grid is used. Second, one generally does not know what values of parameters to assign to very fine grids due to inadequate spatial resolution in field data. As a result, it is necessary to assign effective parameters to the field-scale grid cells. One approach is to use stochastic methods[15] to derive effective parameters. Renormalization methods,[22] which rely on numerical methods, are another means to derive effective parameters. In some instances the governing equations may behave differently at the small scale than at the large scale. For instance, in the case of finger flow[23,24] or funnel flow,[25] the flow occurs on a scale of about 10 cm. To simulate these flow features directly it is necessary to use relatively small grid cells. Using large grid cells without considering these small-scale processes leads to a diffuse solution and the small-scale features are missed. Effectively capturing the dynamics of these small-scale processes into a field-scale grid requires an appropriate procedure for upscaling of the governing equations from the small-scale to the field-grid scale. Such a procedure has been demonstrated[26] for viscous fingering in multiphase flow and is an area of active research. The discussion about process scale poses the question about whether the governing equations maintain a constant form in the progression from the small scale to the large scale. Addressing this question involves the principles currently developed in the field of multiscale science.[27] While these developments originated in the fields of solid mechanics and fluid mechanics, they are currently receiving much attention in hydrology, soil physics, and hydrogeology.
REFERENCES 1. Richards, L.A. Capillary conduction of liquids through porous mediums. Physics 1931, 1, 318–333. 2. Philip, J.R. Steady infiltration from spheroidal cavities in isotropic and anisotropic soils. Water Resour. Res. 1986, 22, 1874–1880.
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3. Paniconi, C.; Putti, M.A. A comparison of picard and newton iteration in the numerical solution of multidimensional variably saturated flow problems. Water Resour. Res. 1994, 30, 3357–3374. 4. Freeze, R.A. Three-dimensional, transient, saturatedunsaturated flow in a groundwater basin. Water Resour. Res. 1971, 7, 347–366. 5. Saad, Y. Iterative Methods for Sparse Linear Systems; PWS Publ. Co.: Boston, MA, 1996. 6. Brandt, A. Multi-level adaptive solutions to boundary value problems. Math. Comput. 1977, 31, 333–390. 7. Huyakorn, P.S.; Thomas, S.D.; Thompson, B.M. Techniques for making finite elements competitive in modeling flow in variably saturated media. Water Resour. Res. 1986, 20, 1099–1115. 8. Rathfelder, K.; Abriola, L.M. Mass conservative numerical solutions of the head-based richards equation. Water Resour. Res. 1994, 30, 2579–2586. 9. Forsyth, P.A.; Wu, Y.S.; Pruess, K. Robust numerical methods for saturated-unsaturated flow with dry initial conditions in heterogeneous media. Adv. Water Resour. 1995, 18, 844–856. 10. Diersch, H.-J.G.; Perrochet, P. On the primary variable switching technique for simulating unsaturatedsaturated flows. Adv. Water Resour. 1999, 23, 271–301. 11. Tocci, M.D.; Kelley, C.T.; Miller, C.T. Accurate and economical solution of the pressure-head form of richards’ equation by the method of lines. Adv. Water Resour. 1997, 20, 1–14. 12. Williams, G.A.; Miller, C.T. An evaluation of temporally adaptive transformation approaches for solving richards’ equation. Adv. Water Resour. 1999, 22, 831–840. 13. Paniconi, C.; Wood, E.F. A detailed model for simulation of catchment scale subsurface hydrologic processes. Water Resour. Res. 1993, 29, 1601–1620. 14. Webster, R. Quantitative spatial analysis of soil in the field. In Advances in Soil Science; Stewart, B.A., Ed.; Springer Verlag: New York, 1985; Vol. 3, 1–70. 15. Mantoglou, A.; Gelhar, L.W. Stochastic modeling of large-scale transient unsaturated flow systems. Water Resour. Res. 1987, 23, 37–46. 16. Miller, C.T.; Christakos, G.; Imhoff, P.T.; McBride, J.F.; Pedit, J.; Trangenstein, J.A. Multiphase flow and transport modeling in heterogeneous porous media: challenges and approaches. Adv. Water Resour. 1999, 21, 77–120. 17. Kaluarachchi, J.J.; Parker, J.C. An efficient finite element method for modeling multiphase flow. Water Resour. Res. 1989, 25, 43–54. 18. Bastian, P.; Helmig, R. Efficient fully-coupled solution techniques for two-phase flow in porous media; parallel multigrid solution and large scale computations. Adv. Water Resour. 1999, 23, 199–216. 19. Nassar, I.N.; Horton, R. Heat, water and solute transfer in unsaturated porous media: I. Theory development and transport coefficient evaluation. Trans. Por. Med. 1997, 27, 17–39. 20. Thomas, H.R.; Missoum, H. Three-dimensional coupled heat, moisture, and air transfer in a deformable
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unsaturated soil. Int. J. Num. Meth. Engng. 1999, 44, 919–943. 21. Chounet, L.M.; Hilhorst, D.; Jouron, C.; Kelanemer, Y.; Nicolas, P. Simulation of water flow and heat transfer in soils by means of a mixed finite element method. Adv. Water Resour. 1999, 22, 445–460. 22. King, P.R. The use of renormalization for calculating effective permeability. Transp. Por. Med. 1989, 4, 37–58. 23. Glass, R.J.; Steenhuis, T.S.; Parlange, J.-Y. Wetting front instability as a rapid and far-reaching hydrologic process in the vadose zone. J. Contam. Hydrol. 1988, 3, 207–226.
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24. Nieber, J.L. Modeling finger development and persistence in initially dry porous media. Geoderma 1996, 70, 209–229. 25. Ju, S.-H.; Kung, K.-J.S. Steady-state funnel flow: its characteristics and impact on modeling. Soil Sci. Soc. Am. J. 1997, 61, 416–427. 26. Blunt, M.; Christie, M. How to predict viscous fingering in three-component flow. Transp. Por. Med. 1993, 12, 207–236. 27. Glimm, J.; Sharp, D.H. Multiscale science: a challenge for the twenty-first century. SIAM News 1997, 304, 17, 19.
Forest Ecosystems: Nutrient Cycling Neil W. Foster Canadian Forest Service, Ontario, Sault Ste. Marie, Ontario, Canada
Jagtar S. Bhatti Canadian Forest Service, Northern Forestry Centre, Edmonton, Alberta, Canada
INTRODUCTION
INFLUENCE OF CLIMATE
Nutrients are elements or compounds that are essential for the growth and survival of plants. Plants require large amounts of nutrients such as nitrogen (N), phosphorus (P), carbon (C), hydrogen (H), oxygen (O), potassium (K), calcium (Ca), and magnesium (Mg), but only small amounts of others such as boron (B), manganese (Mn), iron (Fe), copper (Cu), zinc (Zn) and chlorine (Cl) (micronutrients). Forest nutrient cycling is defined as the exchange of elements between the living and nonliving components of an ecosystem.[1] The processes of the forest nutrient cycle include: nutrient uptake and storage in vegetation perennial tissues, litter production, litter decomposition, nutrient transformations by soil fauna and flora, nutrient inputs from the atmosphere and the weathering of primary minerals, and nutrient export from the soil by leaching and gaseous transfers. Each nutrient element is characterized by a unique biogeochemical cycle. Some of the key features of the major nutrients are shown in Table 1. Forest trees make less demand on the soil for nutrients than annual crops because a large proportion of absorbed nutrients are returned annually to the soil in leaf and fine root litter and are reabsorbed after biological breakdown of litter materials. Also, a large portion of nutrient requirement of trees are met through internal cycling as compared with agricultural crops. Nutrient cycling in forest ecosystems is controlled primarily by three key factors: climate, site, abiotic properties (topography, parent material), and biotic communities. The role of each factor in ecosystem nutrient dynamics is discussed and illustrated with selected examples from boreal, temperate, and tropical zones. The importance of ecosystem disturbance to nutrient cycling is examined briefly, since some nutrients are added or lost from forest ecosystems through natural (e.g., fire, erosion, leaching) or human activity (harvesting, fertilization).
Large-scale patterns in terrestrial primary productivity have been explained by climatic variables. In aboveground vegetation, nutrient storage generally increases in the order: boreal < temperate < tropical forests (Table 2). In contrast, forest floor nutrient content and residence time increases from tropical to boreal forests, as a result of slower decomposition in the cold conditions of higher latitudes. In subarctic woodland soils and Alaskan taiga forests, nutrient cycling rates are low because of extreme environmental conditions.[2] Arctic and subarctic forest ecosystems have lower rates of nutrient turnover and primary production because of low soil temperature, a short growing season, low net AET and the occurrence of permafrost. Low temperature reduces microbial activity, litter decomposition rates, and nutrient availability and increases C accumulation in soil. In contrast with high latitudes, conditions in a tropical forest favor microbial activity throughout the year, which generally results in faster decomposition except in situations with periodic flooding, soil dessication, and low litter quality.[3] Rates of plant material decay are an order of magnitude higher in tropical soils than in subarctic woodland soils. The low storage of C and high amount of litter production in highly productive tropical forests contrasts with the high C storage and low litter production in boreal forests (Table 2).
718 Copyright © 2006 by Taylor & Francis
INFLUENCE OF BIOTIC FACTORS Nutrient cycles are modified substantially by tree species-specific controls over resource use efficiency (nutrient use per unit net primary production). Species vary widely in their inherent nutrient requirements and use.[4] These effects can be split into two categories: accumulation into living phytomass and production of various types of nutrient-containing dead Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001709 Copyright # 2006 by Taylor & Francis. All rights reserved.
Forest Ecosystems: Nutrient Cycling
719
Table 1 Features of the major nutrient cycles Element
Major sources for tree uptake
Uptake by the trees
Limiting situations
Carbon
Atmosphere
Atmosphere
Atmospheric concentration may limit growth
Oxygen
Atmosphere
Atmosphere
Waterlogged soils
Hydrogen
Atmosphere
Atmosphere
Extremely acidic and alkaline conditions
Nitrogen
Soluble NO3 and NH4; N2 for nitrogen fixing species
Soil organic matter; atmospheric N2 for nitrogen fixing species
Most temperate forests, many boreal forests and some tropical forests
Phosphorus
Soluble phosphorus
Soil organic matter; adsorbed phosphate and mineral phosphorus
Old soils high in iron and aluminum, common in subtropical and tropical environment
Potassium calcium magnesium
Soluble Kþ=soluble Ca2þ= soluble Mg2þ
Soil organic matter; exchange complex and minerals
Miscellaneous situations and some old soils
phytomass. Rapid accumulation of phytomass is associated with a net movement of nutrients from soil into vegetation. More than half of the annual nutrient uptake by a forest is typically returned to forest floor (litterfall) and soil (fine-root turnover). The subsequent recycling of these nutrients is a major source of available nutrients for forest vegetation. The mean annual litterfall from above-ground vegetation increases from boreal regions to the tropics following the gradient of productivity (Table 2). Nutrient availability is strongly influenced by the quantity and quality of litter produced in a forest. A high proportion of the variation in foliar N concentrations at the continental scale has been
explained by differences between forest types, which in turn has large impact on litter quality and the nutrient content of forest floors. In many temperate and boreal forest ecosystems, microbial requirement for N increases or decreases with labile supplies of soil C. Increased microbial demand for N may temporarily decrease the N availability to trees during the initial decomposition of forest residues with a wide C/N ratio. Microbes immobilize N from the surrounding soil, relatively rapid for readily decomposable organic matter (needle litter), and more slowly for recalcitrant material (branches, boles). Rates of net N mineralization are higher and retention of foliar N is lower in temperate and tropical than
Table 2 Nutrient distribution in different forest ecosystems Vegetation (Mg ha1)
Forest floor (Mg ha1)
Soil (Mg ha1)
Residence time (year)
Carbon Boreal coniferous Temperate deciduous Tropical rain forest
78–93 103–367 332–359
37–113 42–105 7–72
41–207 185–223 2–188
800 200 120
Nitrogen Boreal coniferous Temperate deciduous Tropical rain forest
0.3–0.5 0.1–1.2 1.0–4.0
0.6–1.1 0.2–1.0 0.03–0.05
0.7–2.87 2.0–9.45 5.0–19.2
200 6 0.6
Phosphorus Boreal coniferous Temperate deciduous Tropical rain forest
0.033–0.060 0.06–0.08 0.2–0.3
0.075–0.15 0.20–0.10 0.001–0.005
0.04–1.06 0.91–1.68 0.06–7.2
300 6 0.6
Potassium Boreal coniferous Temperate deciduous Tropical rain forest
0.15–0.35 0.3–0.6 2.0–3.5
0.3–0.75 0.050–0.15 0.020–0.040
0.07–0.8 0.01–38 0.05–7.1
100 1 0.2
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in boreal forest soils. Nitrogen limitation of productivity, therefore, is weak in tropical forests and increases from temperate to boreal and tundra forest systems. Trees may obtain organic N and P from the soil via mycorrhizae or by relocation from older foliage prior to abscission, and thereby, partly reduce their dependence on soil as a source of inorganic nutrients. Increased understanding of the fundamental relationships between soil properties and plant nutrients requirements will most likely come from examination of plant–fauna–microbe interactions at root surfaces (rhizosphere), rather than in the bulk soil.
INFLUENCE OF ABIOTIC FACTORS Forests have distinctive physiographic, floristic, and edaphic characteristics that vary predictably across the landscape within a climatically homogeneous region. Differences in the elemental content of parent material influence the tree species composition between and within a landscape unit. For example, wind deposited soils, which support hardwood or mixed wood forest, are likely to be fine textured with high nutrient supplying capacity. In contrast, outwash sands that often support pine forests are coarse textured and infertile. Heterogeneity within the landscape results in sites differing in microclimatic conditions, and physical and chemical properties, which produces different geochemical reaction rates and pools of available nutrients in soil. Soil type and topographic–microclimate interactions are important feedbacks that influence biological processes, such as the rate of N mineralization in soil. Low P availability is a characteristic of geomorphically old, highly weathered tropical, subtropical, and warm temperate soils.[3] The type and age of parent material from which the soil is derived can influence the base status and nutrient levels in soil. Soils in glaciated regions are relatively young and rich in weatherable minerals. Mineral weathering is an important source of most nutrients for plant uptake, with the exception of N. Nutrient availability is regulated by the balance between weathering of soil minerals and precipitation, adsorbtion, and fixation reactions in soil. Edaphic conditions can exert a strong influence on forest productivity and produce considerable variation in nutrient cycling processes. Soils with low N, P, or pH support trees with low litter quality (high in lignin and tannins that bind N) that decomposes slowly. Edaphic limitations on growth may be compensated for by an increase in rooting density and depth. Some late-succession or tolerant species have a shallower root distribution relative to intolerant pioneer species and are adapted to sites where nutrients and moisture
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Forest Ecosystems: Nutrient Cycling
are concentrated at the soil surface. In contrast, nutrient uptake from sub-soil horizons is more important in highly weathered warm temperate soils where nutrient depletion takes place deeper in the soil.
ROLE OF DISTURBANCE Disturbances such as fire, harvesting, hurricanes, or pests affect nutrient cycling long after the event. In fire-dominated ecosystems, intensive wildfire results in a horizontal and vertical redistribution of ecosystem nutrients. Redistribution results from the combined effects of the following processes: 1) oxidation and volatilization of live and decomposing plant material; 2) convection of ash particles in fire generated winds; 3) water erosion of surface soils; and 4) percolation of solutes through and out of the soil. The relative importance of these processes varies with each nutrient and is modified by differences in fire intensity, soil characteristics, topography, and climatic patterns. Expressed as a percentage of the amount present in vegetation and litter before fire, the changes often follow the order: N > K > Mg > Ca > P Harvesting removes nutrients from the site and interrupts nutrient cycling temporarily. The recovery of the nutrient cycle from harvest disturbance is dependent partly on the rate of re-establishment of trees and competing vegetation. Re-vegetation may occur within months in the tropics, 2–5 years in temperate regions, and longer in boreal and tundra regions.[5] Recovery assumes that the soil’s ability to supply nutrients to plant roots has not been altered by disturbance. If nutrients cannot be supplied by the soil at rates sufficient to at least maintain the rate of growth of the previous forest then fertilization may be necessary to maintain site productivity. Nutrient cycling and the impacts of disturbance on nutrient cycling, have been examined thoroughly in many representative world forests. The impact of natural disturbances and management practices on nutrient cycling processes are generally characterized of the stand or occasionally on a watershed basis. There is a growing demand from policy makers and forest managers for spatial estimates on nutrient cycling at local, regional, and national scales. The availability of N, P, and K in soil largely determines the leaf area, photosynthetic rate, and net primary production of forest ecosystems. Forest management practices that produce physical and chemical changes in the soil that accentuate the cycle of nutrients between soil and trees, may increase
Forest Ecosystems: Nutrient Cycling
forest productivity. Clear-cut harvesting and site preparation practices (mechanical disturbance, slash burning) remove nutrients from soil in tree components and by increased surface runoff, soil erosion, and off-site movement of nutrients in dissolved form or in sediment transport. In the tropics, potential negative impacts associated with complete forest removal and slash burning are greatest because a larger proportion of site nutrients are contained in the living biomass. Environmental impacts associated with clear-cutting and forest management in general, are confounded by climatic, topographic, soil, and vegetation diversity associated with the world’s forests. Best forest management practices can be utilized to control negative impacts on nutrient cycling.
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721
REFERENCES 1. Glossary of Soil Science Terms; Soil Science Society of America: Madison, WI, 1996; 134 pp. 2. Van Cleve, K.; Chapin, F.S., III; Dyrness, C.T., III; Viereck, L.A. Element cycling in taiga forests: state factor control. Bioscience 1991, 41, 78–88. 3. Vitousek, P.M.; Stanford, R.L., Jr. Nutrient cycling in moist tropical forest. Ann. Rev. Ecol. Syst. 1986, 17, 137–167. 4. Cole, D.W.; Rapp, M. Elemental cycling in forest ecosystems. In Dynamic Properties of Forest Ecosystems; Reichle, E.D., Ed.; Cambridge University Press: London, 1981; 341–409. 5. Keenan, R.J.; Kimmins, J.P. The ecological effects of clear-cutting. Environ. Rev. 1993, 1, 121–144.
Forest Ecosystems: Soils Associated with Major Ken Van Rees University of Saskatchewan, Saskatoon, Saskatchewan, Canada
INTRODUCTION Soil is defined as the unconsolidated mineral or organic material that occurs at the Earth’s surface and is capable of supporting plant growth. Forest soils are those soils that have developed underneath forest vegetation.[1] Forests cover approximately 29% of the world’s land surface and play a key role in most ecosystems except for the tundra, deserts, some grasslands, and wetlands. Forests and forest soils contain about 60% of the carbon contained in the Earth’s land surface and thus are an integral part in the global carbon cycle.[2] Soil development or genesis beneath forest ecosystems is influenced by a number of different factors. These factors include the type and nature of the forest vegetation, parent material and topography, climate, human or organism influence, and the amount of time that these factors have been influencing soil development.[3] All these factors combined together can result in soils with different physical, chemical, and biological properties that are unique to those conditions and provide the framework for how soils are classified. Generally there are two main classification systems used in the world: the U.S. soil taxonomic[4] and the FAO systems.[5] Soils types will vary around the world, but some generalizations can be made based on the major forest biomes that exist today. The major forest biomes include boreal and coniferous forests, temperate deciduous=mixed forests, scrub and woodlands, temperate rain forest, tropical rain forests, and tropical monsoon=deciduous forests. A generalized vegetation map of the world showing most of these forest biomes is provided in Fig. 1. Typical soil types associated with these forests are summarized in Table 1 and discussed later for each major forest biome.
forests are generally acidic and form on sandy deposits from glaciation and range in thickness from >1 m to very shallow (30 cm
a
Classes as defined in Agriculture Canada Expert Committee on Soil Survey, 1987. The Canadian System of Soil Classification.
under coniferous forests than deciduous forests: dense conifer canopies intercept much of the incoming solar radiation, thereby reducing the solar heating of the soils underneath, especially of wet soils. Delayed soil heating often implies delayed root growth, thereby shortening the effective growing season and hence forest growth. Fine roots are also sensitive to soil acidification:[7] slowly soluble soil Al may convert to toxicologically active Al as the forest soil acidifies either naturally during the course of their development, or on account of acid deposition.
INFLUENCE OF NUTRIENT SUPPLIES AND AVAILABILITIES Matters dealing with nutrient supplies, retention and availability are of particular importance to sustainable forest production, as follows:
Long-term nutrient supplies of forest ecosystems need to be sustainable in principle. Additions of nutrients to each site come from external sources (atmospheric accretions, liming, and fertilizer), and from internal sources (weathering of primary soil minerals, biochemical cycling). Under natural conditions, origin and type of soil parent material are strong determinants of rate of weathering and related nutrient supplies.
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Nutrient retention and release involves numerous reactions, including ion sorption and desorption on mineral and organic colloids; precipitation by metal oxides; complexation by humic substances; immobilization of nutrient ions by microorganisms and SOM mineralization. All these processes are influenced by soil texture, SOM content, cation exchange capacity (CEC), pH, base saturation, aeration, and prevailing soil temperature and moisture regimes.
Nutrient availability results from the net cumulative difference between supplies, immobilization, leaching, mineralization, and past uptake, and is also controlled by chemical equilibria. Potential fertility of a soil can provisionally be appraised from simple field observations. For example, favorable contents and distribution of SOM and clay imply improved N, P and base cation supply, and the presence of black minerals in the parent material may indicate K and Mg sufficiency. To be reliable, such observations must be supplemented by appropriate soil analysis. The effect of soil parent material, via the continuing weathering of primary minerals, is often reflected in the species composition of natural forests. For example, in central regions of eastern North America, soils derived from calcareous shales often support, e.g., basswood, white ash, yellow-poplar and hickory, while soils
Forest Soils Properties and Site Productivity
731
Fig. 1 Soils with contrasting productivity in the Atlantic Region of Northeastern North America. Left: brunisolic podsol supporting vigorous forest of northern tolerant hardwoods. Right: gleyed podsol supporting a pure black spruce stand. Note uniformly brown color, structure (granular to subangular blocky), and abundance of roots throughtout.
derived from acid sedimentary rocks support high percentages of beech, yellow birch, red maple and certain oaks. As well, white cedar and eastern red cedar grow better on calcareous soils than on acid soils. In Sweden, site productivity is grouped by calcium content of the soil parent material: soils derived from calcium-poor substrates commonly support Scots pine at low productivity; soils with intermediate calcium availability support pine and mixed conifer forests with high productivity; soils derived from basic igneous sedimentary substrates support productive stands of Norway spruce and hardwoods.
CA, MG, K, P AND TRACE ELEMENTS In areas where soils are very old and deeply weathered (e.g., tropical and subtropical regions in Africa, Asia, Australia, and Central and South America), or where soils have been heavily cropped, forest productivity is often limited because of limited supplies of Ca, Mg, K, P and=or micronutrients such as Zn, Cu, and B.[8] Such soils often consist of abundant accumulation
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of Al and Fe sesquioxides, which typically produce soils with high anion exchange capacities (AEC), but low CEC. As a result, nutrient elements such as K, Mg, and Ca are generally in short supply and severe losses of forest productivity are likely to occur when such soils are stripped of their natural forest vegetation. Such soils, furthermore, may loose their originally friable consistency with gradual SOM loss and become cementation when exposed to air and allowed to dry. Areas that have been covered by glaciers in the recent past and currently have a temperate to boreal climate can support productive forests set within the limits set by climate and soil depth. This can be attributed to the continuing release of Ca, Mg, K, and P through natural weathering of the ground-up bedrock (till). Soils in these areas generally have low accumulations of Fe and Al sesquioxides, except in areas of high soil acidity where forest productivity may decrease as a result of advanced podsolization, i.e., the formation of Fe- and organic matter cemented hardpans within the B horizon. Except for N, mineral deficiencies are infrequently encountered in these areas.
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Forest Soils Properties and Site Productivity
N AVAILABILITY
REFERENCES
In boreal and sub-boreal climates, forest productivity is commonly restricted by low N availability, which is the result of slow SOM turn-over rates. Under these conditions, the forest floor is the principal source of available N: the A horizon is—more often than not—strongly leached, poorly developed or absent, and N in the B layers is essentially unavailable. In these soils, N availability is further adversely affected by high soil acidity, impeded drainage, and restricted soil aeration. In contrast, soils with mesic or warmer temperature regimes have SOM-enriched A layers with high levels of available N. As shown in many studies,[2] site quality on these soils rises with increasing depth of the A layer.
1. Pritchett, L.W.; Fisher, F.R. Properties and Management of Forest Soils, 2nd Ed.; Wiley: New York, 1987; 494 pp. 2. Carmean, W.H. Forest site quality evaluation in the United States. Adv. Agron. 1975, 27, 209–269. 3. Klinka, K.; van der Horst, W.D.; Nuszdorfer, F.C.; Harding, R.G. An ecosystematic approach to forest planning. For. Chron. 1980, 56, 97–103. 4. Zahner, R. Water deficit and growth of trees. In Water Deficits and Plant Growth; Kozlowski, T.T., Ed.; Academic Press: New York, 1968; 191–254. 5. Drew, M.C. Soil aeration and plant root metabolism. Soil Sci. 1992, 154, 259–268. 6. Wilde, S.A.; Iyer, J.G.; Tanzer, C.; Trautman, W.L.; Watterston, K.G. Growth of Wisconsin Coniferous Plantations; Research Bulletin 262, University of Wisconsin: Madison, WI, 1965; 80 pp. 7. Reuss, J.O.; Walthall, P.M.; Roswall, E.C.; Hopper, R.W.E. Aluminum solubility, calcium–aluminum exchange, and pH in acid forest soils. Soil Sci. Soc. Am. J. 1990, 54, 374–380. 8. Stone, E.L. Microelement nutrition of forest trees: a review. In Forest fertilization—Theory and Practice; Tennessee Valley Authority: Knoxville, TN, 1968; 132–175. 9. Burger, J.A.; Kelting, D.L. Using soil quality indicators to assess forest stand management. For. Ecol. Mgmt. 1999, 122, 155–166. 10. Kimmins, J.P.; Scoullar, K.A. FORCYTE 10; Faculty of Forestry, University of British Columbia: Vancouver, BC, 1983; 112 pp. 11. Bhatti, J.S.; Foster, N.W.; Oja, T.; Moayeri, M.H.; Arp, P.A. Modelling potentially sustainable biomass productivity in jack pine forest stands. Can. J. Soil. Sci. 1998, 78, 105–113.
CONCLUSIONS Forest growth restrictions occur on soils with nutrientpoor parent materials, inefficient water and nutrient storage and retrieval capacities, unfavorable pH, low SOM contents, and extreme texture (sand, clay). Some of these soil restrictions can—in part—be corrected by silvicultural means such as change of forest cover type, control of stand density, fertilization, irrigation, and artificial drainage. All of these growth restrictions have been considered in recent efforts to develop soil quality indices for monitoring sustainability of current forest management practices.[9] Additional efforts are being made to quantify the relationships between soil and forest production by way of modeling.[10,11]
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Forest Soils: Calcium Depletion Tom G. Huntington United States Geological Survey (USGS), Augusta, Maine, U.S.A.
INTRODUCTION Calcium depletion in forest soils is the process by which Ca stored in the soil in exchangeable, organic, and mineral-bound forms is gradually lost in response to natural and anthropogenic mechanisms. The primary natural mechanism is the weathering of soil minerals and leaching of dissolved Ca to ground and surface water. The primary anthropogenic mechanisms are removal of Ca in forest products and the acceleration of leaching losses by elevated atmospheric acidic deposition.[1,2] When the rate of Ca losses through leaching and harvest removals exceeds the rate of replenishment through atmospheric deposition and the weathering of primary minerals, soil Ca is depleted. These input and output processes are shown schematically in Fig. 1. Calcium depletion results in decreased Ca availability to plants and lower Ca concentrations in soil, surface, and ground water.
WHAT IS THE EVIDENCE FOR CALCIUM DEPLETION? There is a growing body of evidence that supports the hypothesis that forest soils in the eastern United States and in Europe are experiencing Ca depletion. The evidence can be grouped in three major categories: 1) direct re-measurements over time; 2) mass balance studies; and 3) indirect evidence that is consistent with decreasing Ca. Several studies in Europe[3–5] and the US[6–9] have found significant decreases in exchangeable Ca in forest soil following decades of acidic deposition and uptake by aggrading forests. These re-measurement studies are the most direct evidence that forest soils in many regions are experiencing net Ca depletion. Many studies have measured the input and output fluxes of Ca in forest ecosystems and concluded that the rates of loss substantially exceed inputs.[10–13] Examples of pools and fluxes of Ca determined in biogeochemical studies of this kind are summarized in Table 1. In these studies, investigators have attempted to measure atmospheric inputs, vegetation uptake, and soil leaching losses over a period of several years to determine average annual rates. The rate of weathering is usually estimated indirectly. There is Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120018495 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
more uncertainty in the weathering estimate than in other estimates but it can frequently be constrained using silica export of strontium isotope ratios. The balance of evidence from the majority of intensively studied sites indicates that Ca outputs exceed inputs. The potential for weathering resupply remains an important uncertainty, but the weight of evidence suggests that declines in Ca reserves in forest ecosystems are ongoing, arguing that weathering rates are too slow to replenish Ca.[13,14] There have also been a substantial number of studies that have provided insight into the status of forest soil Ca using indirect evidence. Strontium isotope ratio analysis has been used to infer ongoing Ca depletion in the northeastern United States.[15,16] Trends in stem wood chemistry have also been shown to be consistent with Ca depletion in red spruce dominated forests of the northeastern United States.[17,18] Studies have also reported that the failure of stream water to recover from acidification despite large reductions in sulfur deposition is indicative of Ca depletion.[19] Long-term trends in stream water chemistry and sulfate deposition at several forested watersheds at the Coweeta Hydrologic Laboratory in North Carolina and in the Shenandoah National Park in Virginia support the hypothesis that soil retention of atmospherically derived sulfate has decreased in recent years[20,21] supporting the mechanism for ongoing Ca depletion.[1,2] Many streams in the eastern United States have experienced statistically significant decreases in Ca concentrations that may be related to soil depletion.[10] Other studies have demonstrated positive responses in soil and tree health and vigor following fertilization with Ca suggesting that Ca was a limiting nutrient at these forest sites.[22–24]
WHY IS CALCIUM DEPLETION A THREAT TO FOREST ECOSYSTEMS? Calcium depletion has been implicated in the failure of stream water alkalinity to recover in spite of significant decreases in acidic deposition.[19,25,26] Decreases in Ca availability have been suggested as factors influencing health and vigor of fish,[27] snails,[28] birds,[29] and mollusks.[30] Calcium depletion is of concern for a 733
734
Forest Soils: Calcium Depletion
Atmospheric Deposition of Ca Ca
Rain and Dust Ca
Ca2+
Ca2+ Ca2+
Forest Floor
Ca2+
Leaching Loss To Streams
Ca
Ca
Ca2+
Ca2+
Ca2+
Tree Uptake
Ca2+
Ca2+
Ca
Exchangeable Soil Calcium Mineral Soil
Mineral Weathering
Ca
variety of reasons related to the many critical roles that Ca plays in tree physiology and the likelihood that Ca limitation will adversely influence many aspects of forest function.[31] Calcium limitation in forest
Fig. 1 Calcium cycling in forest ecosystems. Inputs to the available pool of exchangeable soil calcium result from atmospheric deposition in precipitation and dust and the weathering of primary minerals. Outputs from this pool result from plant uptake and removal of wood products and leaching from the soil to streams.
ecosystems is thought to adversely influence disease resistance, wound repair, frost hardiness, and lignin synthesis in trees.[31] Calcium depletion is considered to be an especially serious threat to tropical
Table 1 Soil calcium pools, ecosystem fluxes, and net depletion, from selected forest sites in the southeastern United Sates
Predominant species
Soil exchange pool (kg ha1)
Total soil pool (kg ha1)
Net wood incrementb (kg ha1 yr1)
Total atmospheric deposition (kg ha1 yr1)
Soil leaching (kg ha1 yr1)
Net depletion (kg ha1 yr1)
Location
Ref.a
Stewart Co., Georgia
[33]
Pinus taeda L.
840
840
6
3.2
1.1
3.9
Duke Forest, North Carolina
[13]
Pinus taeda L.
2130
4900
14
8.1
8.1
13.6
Panola Mountain, Georgia
[34]
Carya, Quercus, Liriodendron Tulipifera Pinus taeda L.
2200
9500
10
2.3
2.9
10.7
Clemson, South Carolina
[35]
Pinus taeda L.
1450
NDd
3.4
2.9
3.9
4.4
Oak Ridge, Tennessee
[13]
Pinus taeda L.
6900
8600
5.5
5.4
19.2
19.3
Huntington Forest, New York
[13]
Acer saccharum Marsh., Fagus grandifolia, Ehrh., Acer rubrum L., Betula lutea Michx. F., Picea rubens Sarg
606
120,000
2.7
5.1
15
12.6
(Continued)
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Forest Soils: Calcium Depletion
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Table 1 Soil calcium pools, ecosystem fluxes, and net depletion, from selected forest sites in the southeastern United Sates (Continued)
Predominant species
Soil exchange pool (kg ha1)
Total soil pool (kg ha1)
Net wood incrementb (kg ha1 yr1)
Total atmospheric deposition (kg ha1 yr1)
Soil leaching (kg ha1 yr1)
Net depletion (kg ha1 yr1)
Location
Ref.a
Thompson Forest, Washington
[13]
Pseudotsuga menziesii, Alnus rubra
1093
46,000
1.5
8.8
13
5.7
Howland, Maine
[13]
Picea rubens Sarg., Abies balsamea
288
59,000
5.1
4.6
8.0
8.5
Sabah, Malaysia
[36]
Acacia mangium
502
727
47e
< 4.0
ND
ND
Nordmoen, Norway
[13]
Picea abies L. Karst
194
29,000
6.1
5.4
9.0
9.8
Turkey lakes, Ontario
[13]
Acer saccharum Marsh., Betula aleghaniensis Britton, Ostrya viginianna Mill. Acer rubrum L.
671
59,000
1.3
9.3
88
80
St.-Hippolyte Quebec
[37]
Acer saccharum Marsh.
ND
ND
ND
3.0
13.3
ND
a
Reference numbers correspond to reference list. Net wood increment assumes that merchantable (stemwood) will be harvested and removed from the site. Whole-tree harvesting would result in greater removals. c GSMNP, Great Smoky Mountains National Park. d ND, not determined. e Estimated from growth at 45 months, 398 kg ha1 was reportedly removed during harvest. (From Ref.[34].) b
forests growing on highly weathered soils in the tropics.[36]
ecosystem recovery following reductions in emission and deposition of acidic compounds.
CONCLUSIONS
ACKNOWLEDGMENTS
Calcium depletion in forest soils is a natural pedogenic process that can be accelerated by harvest removals and acidic deposition. Several lines of evidence support the fact that Ca depletion is an ongoing process in many forest soils. Direct re-measurements have shown Ca depletion in the eastern U.S. and Europe. Mass balance studies strongly suggest outputs exceed inputs in many intensively studied forest catchments. Indirect evidence from strontium isotope analysis, stem wood chemistry, fertilization experiments, and other studies are also consistent with ongoing Ca depletion. Calcium depletion is a threat to forest ecosystems because decreases in Ca in soils can ultimately adversely influence health and vigor of sensitive trees, fish, snails, birds, and mollusks. Ca Depletion is also a threat because it can delay forest and associated aquatic
This analysis was supported by the U.S. Geological Survey’s (USGS) Water Energy and Biogeochemical Budgets, Atmospheric Deposition, and Hydrologic Benchmark Network Programs.
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REFERENCES 1. Reuss, J.O.; Johnson, D.W. Deposition and Acidification of Soils and Waters; Springer-Verlag: New York, 1986. 2. Robarge, W.P.; Johnson, D.W. The effects of acidic deposition on forested soils. Adv. Agron. 1992, 47, 1–83. 3. Bergkvist, B.; Folkeson, L. The influence of tree species on acid deposition, proton budgets, and element fluxes in south Swedish forest ecosystems. Ecol. Bull. 1995, 44, 90–99.
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4. Falkengren-Grerup, U.; Eriksson, H. Changes since soil, vegetation, and forest yield between 1947 and 1988 in beech and oak sites in southern Sweden deciduous forest soils. For. Ecol. Manag. 1990, 38, 37–53. 5. Wesselink, L.G.; Meiwes, K.J.; Matzner, E.; Stein, A. Long term changes in water and soil chemistry in spruce and beech forests, Solling, Germany. Environ. Sci. Technol. 1995, 29, 51–58. 6. Trettin, C.A.; Johnson, D.W.; Todd, D.E.J. Forest nutrient and carbon pools: a 21-year assessment. Soil Sci. Soc. Am. J. 1999, 63, 1436–1448. 7. Knoepp, J.D.; Swank, W.T. Long-term soil chemistry changes in aggrading forest ecosystems. Soil Sci. Soc. Am. J. 1994, 58, 325–331. 8. Richter, D.D.; Markewitz, D.; Wells, C.G.; Allen, H.L.; April, R.; Heine, P.R.; Urrego, B. Soil chemical change during three decades in an old-field loblolly pine (Pinus taeda L.) ecosystem. Ecology 1994, 75, 1463–1473. 9. Johnson, A.H.; Anderson, S.B.; Siccama, T.G. Acid rain and soils of the Adirondacks: I. Changes in pH and available calcium. Can. J. For. Res. 1994, 24, 193–198. 10. Huntington, T.G.; Hooper, R.P.; Johnson, C.E.; Aulenbach, B.T.; Cappellato, R.; Blum, A.E. Calcium depletion in a southeastern United States forest ecosystem. Soil Sci. Soc. Am. J. 2000, 64, 1845–1858. 11. Adams, M.B.; Burger, J.A.; Jenkins, A.B.; Zelazny, L. Impact of harvesting and atmospheric pollution on nutrient depletion of eastern hardwood forests. For. Ecol. Manag. 2000, 138, 301–319. 12. Federer, C.A.; Hornbeck, J.W.; Tritton, L.M.; Martin, W.C.; Pierce, R.S.; Smith, C.T. Long-term depletion of calcium and other nutrients in eastern US forests. Environ. Manag. 1989, 13, 593–601. 13. Johnson, D.W.; Lindberg, S.E. Atmospheric Deposition and Forest Nutrient Cycling; Springer-Verlag: New York, 1992. 14. Turner, R.S.; Cook, R.B.; Van Miegroet, H.; Johnson, D.W.; Elwood, J.W.; Bricker, O.P.; Lindberg, S.E.; Hornberger, G.M. Watershed and Lake Processes Affecting Surface Water Acid–Base Chemistry. In Acid Deposition: State of Science and Technology, Rep. 10, Natl. Acid Precip., Assess. Program, Washington, DC, Nov., 1990; 1990, 1–167. 15. Miller, E.K.; Blum, J.E.; Friedland, A.J. Determination of soil exchangeable-cation loss and weathering rates using Sr isotopes. Nature 1993, 362, 438–441. 16. Bailey, S.W.; Hornbeck, J.W.; Driscoll, C.T.; Gaudett, H.E. Calcium inputs and transport in a base poor forest ecosystem as interpreted by Sr isotopes. Water Resour. Res. 1996, 32, 707–719. 17. Bondietti, E.A.; Momoshima, N.; Shortle, W.C.; Smith, K.T. A historical perspective on divalent cation trends in red spruce stemwood and the hypothetical relationship to acidic deposition. Can. J. For. Res. 1990, 20, 1850–1858. 18. Shortle, W.C.; Smith, K.T.; Minocha, R.; Larwence, G.B.; David, M.B. Acidic deposition, cation mobilization, and biochemical indicators of stress in health red spruce. J. Environ. Qual. 1997, 26, 871–876.
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19. Stoddard, J.L.; Jeffries, D.S.; Lu¨kewille, A.; Clair, T.A.; Dillon, P.J.; Driscoll, C.T.; Forsius, M.; Johannessen, M.; Kahl, J.S.; Kellogg, J.H.; Kemp, A.; Mannio, J.; Monteith, D.T.; Murdoch, P.S.; Patrick, S.; Rebsdorf, A.; Skjelkva˚le, B.L.; Stainton, M.P.; Traaen, T.; Van_Dam, H.; Webster, K.E.; Wieting, J.; Wilander, A. Regional trends in aquatic recovery from acidification in North America and Europe. Nature 1999, 401, 575–578. 20. Johnson, D.W.; Swank, W.T.; Vose, J.M. Simulated effects of atmospheric sulfur deposition on nutrient cycling in a mixed deciduous forest. Biogeochemistry 1993, 23, 169–196. 21. Ryan, P.F.; Hornberger, G.M.; Cosby, B.J.; Galloway, J.N.; Webb, J.R.; Rastetter, E.B. Changes in the chemical composition of stream water in two catchments in the Shenandoah National Park, Virginia, in response to atmospheric deposition of sulfur. Water Resour. Res. 1989, 25, 2091–2099. 22. Moore, J.-D.; Camire, C.; Ouimet, R. Effects of liming on the nutrition, vigour, and growth of sugar maple at the Lake Claire Watershed, Quebec, Canada. Can. J. For. Res. 2000, 30, 725–732. 23. Long, R.P.; Horsley, S.B.; Lilja, P.R. Impact of forest liming on growth and crown vigor of sugar maple and associated hardwoods. Can. J. For. Res. 1997, 27, 1560–1573. 24. Nilsson, L.W.; Wiklund, K. Nutrient balance and P, K, Ca, Mg, S and B accumulation in a Norway spruce stand following ammonium sulphate application, fertigation, irrigation drought and N-free-fertilisation. Plant Soil 1995, 168, 437–446. 25. Kirchner, J.W.; Lydersen, E. Base cation depletion and potential long-term acidification of Norwegian catchments. Environ. Sci. Technol. 1995, 29, 1953–1960. 26. Lawrence, G.B.; David, M.B.; Lovett, G.M.; Murdoch, P.S.; Burns, D.A.; Stoddard, J.L.; Baldigo, B.P.; Porter, J.H.; Thompson, A.W. Soil calcium status and the response of stream chemistry to changing acidic deposition rates in the Catskill Mountains of New York. Ecol. Appl. 1999, 9, 1059–1072. 27. Bulger, A.J.; Cosby, B.J.; Webb, J.R. Current, reconstructed past, and projected future status of brook trout (Salvelinus fontinalis) streams in Virginia. Can. J. Fish. Aquat. Sci. 2000, 57, 1515–1523. 28. Graveland, J. Avian eggshell formation in calcium-rich and calcium-poor habitats: importance of snail shells and anthropogenic calcium sources. Can. J. Zool. 1996, 74, 1035–1044. 29. Graveland, J.; van_der_Wal, R.; van_Balen, J.H.; van_Noordwijk, A.J. Poor reproduction in forest passerines from decline of snail abundance on acidified soils. Nature 1994, 368, 446–448. 30. Wareborn, I. Changes in land mollusc fauna and soil chemistry in an inland district in southern Sweden. Ecography 1992, 15, 62–69. 31. McLaughlin, S.B.; Wimmer, R. Tansley review no. 104. Calcium physiology and its role in terrestrial ecosystem processes. New Phytol. 1999, 142, 373–417. 32. Johnson, D.W.; Todd, D.E. Nutrient cycling in forests of Walker Branch Watershed, Tennessee: Roles of
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uptake and leaching in causing soil changes. J. Environ. Qual. 1990, 19, 97–104. 33. Huntington, T.G. Assessment of the potential role of atmospheric acidic deposition in the pattern of southern pine beetle infestation in the northwest Coastal Plain Province of Georgia, 1992–1995. In U.S. Geological Survey Water Resources Investigation Report 96-4131; U.S. Geological Survey: Reston, VA, 1996; 75. 34. Huntington, T.G. The potential for calcium depletion in forest ecosystems of southeastern United States: review and analysis. Global Biogeochem. Cycles 2000, 14, 623–638.
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35. Johnson, D.W.; Kelly, J.M.; Swank, W.T.; Cole, D.W.; Van Miegrot, H.; Hornbeck, J.W.; Pierce, R.S.; Van Lear, D. The effects of leaching and whole tree harvesting on cation budgets of several forests. J. Environ. Qual. 1988, 17, 418–424. 36. Nykvist, N. Tropical soils can suffer from a serious deficiency of calcium after logging. Ambio 2000, 29, 310–313. 37. Hendershot, W.H.; Courchesne, F. Effect of base cation addition on soil chemistry in a sugar maple forest of the lower Laurentians Quebec. Can. J. For. Res. 1994, 24, 609–617.
Future of Soil Science: Role of Soils Richard W. Arnold United States Department of Agriculture, Washington, D.C., U.S.A.
INTRODUCTION Recent studies indicate that during the Anthropocene humanity has experienced exponential growth of consumption, generation of waste, and population.[1] The human economy depends on the planet’s natural capital that provides all ecological services and natural resources, and since about 1980 the human demands have exceeded the capacity of the earth to sustain such use.[2] Cultural attitudes determine the role of soils in today’s world as our fragmented global community struggles to resolve the global issues of food security, environmental protection, and overall sustainability. A variety of world views influences the search for a sustainable, socially acceptable balance among soil functions that provides for viable economic growth and development, safe healthy environments, and intergenerational equity.[3] Linking entire social systems in a web of production, distribution, and consumption, agriculture often foreshadows the degree of economic well-being.[4] Because agriculture operates simultaneously in the realms of ecology and economics, each of which marks time by different clocks, decisions affecting food security and environmental protection have become increasingly complex and variable over time and space.
THE PEDOSPHERE Soils are a critical interface between society and natural resources. Thus, the basic principles of the organization and functioning of the Earth’s soil cover, the pedosphere, can provide a scientific basis for programs addressing global sustainability throughout the 21st century.[5] Natural soils result from the interaction of processes taking place over time on the Earth’s surface. Most involve gases and liquids that transform the solid phase of the surficial materials into features recognized as soils. These processes are influenced by soil-forming factors— namely, climate, biota, topography, parent material, and time—leading to great heterogeneity in the world’s soil cover. Geomorphic processes that alter the landscape by erosion, transport, and deposition of rocks and sediments, and the interaction of biological systems with soils are all subject to major modifications associated Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042624 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
with global and regional climate changes. The result is an intricate patchwork of soils, ranging in size from a few square meters to thousands of square kilometers. For millennia, naturally evolving soils were dominant in the world, and determining the properties and distributions of major kinds of soils and their local geographic associates enabled societies to effectively tap these resources to satisfy their needs. Soils provided habitats for plants, animals, and micro-organisms. Soils possessed the capacity for fertility and potential productivity because of water, physical support, and biological interactions that provided nutrients.[6] Mapping the pedosphere and deciphering the sequence of events and processes causing such complexity have revealed a multidimensional hierarchy that is meaningful for assessing many kinds of soils and predicting soil-related behavior.
ALTERED ECOSYSTEMS For more than a century, scientific studies of soils as natural independent entities on the Earth’s surface have contributed to a better understanding of the interconnectivity of the Earth’s systems.[7] As societies introduced more and more invasive procedures, they drastically altered ecosystem processes and biogeochemical cycles. Although some ecosystems have been enhanced, more have been degraded and are being used unsustainably.[8] Now it has become relevant to monitor, predict, and mediate the behavior and responses of both natural and artificial soil environments and landscapes. It is believed that many changes being made in ecosystems are increasing the likelihood of detrimental nonlinear changes in the future.[1] With increases in the size of human population and its increasing rate of consumption, the available natural resources are stressed, some beyond their limits of resilience. One estimate is that human resource use in 2000 was about 20% above the global carrying capacity.[2] When soils are so stressed, they are unable to return to their former productive states without massive external inputs. Thus, sustainable integration of societal desires and natural resource capabilities is commonly jeopardized. The role of soils, consequently, can be viewed as the set of trade-offs among their various functions, as determined by current society. 741
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FUNCTIONS OF SOILS Functions of soils commonly include: 1) to promote biomass transformations; 2) to serve as the Earth’s geomembrane to filter and buffer; 3) to provide biological habitats; 4) to provide usable materials; and 5) to serve as sources and repositories of our cultures.[9] Soils are primarily used by most people for the production of food, feed, fuel, and fiber. The capacity to store and release water and the ability to renew, store, and release plant nutrients have dominated agronomic and forestry research and practical experimentation for many years. Biomass transformations are highly dependent on the microbiological populations that inhabit soils and facilitate the formation and use of beneficial compounds. The pedosphere is a sensitive geomembrane, which mediates the transfer of air, water, and energy into, out of, and among the biosphere, atmosphere, hydrosphere, and the lithosphere (Fig. 1). Temperatures are moderated with depth, and moisture and associated compounds are filtered, retained, stored, and transferred in ways that contribute to clean, healthy environments. Soils are the habitat for millions of organisms, ranging from cellular bacteria to burrowing animals. Communities of micro-organisms decompose organic materials, facilitate the release of mineral elements,
Future of Soil Science: Role of Soils
and produce the chemical and biological compounds essential for life on Earth.[6] Many soils are directly used as raw materials for constructing dams and foundations; others are source materials for landscaping industrial and urban sites; and some are ingredients for bricks and ceramic products. Most transportation networks and urban communities rest on soils. In addition, soils are excavated to create disposal sites for society’s numerous wastes. Soils that are disturbed or removed from their natural environments are commonly called ‘‘dirt.’’ As such, displaced soil materials are generally considered a nuisance in our daily activities and need to be washed out, removed, and personal contact with them minimized. Historically, stigma was often attached to those associated with the ‘‘filth and dirt’’ of using and managing soils.[10] In the stories of most indigenous cultures, the Earth is sanctified and revered as a vital element of nature, thereby reinforcing humankind’s link with it. This sacredness remains in the use of soils as cemeteries, and as places where the spirits of ancestors reside. Archeological investigations generally involve deciphering the memories of times and events recorded in soil properties.
CONTINUING NEEDS
Fig. 1 The pedosphere results from the interaction throughout space and time of the atmosphere, biosphere, and hydrosphere with the lithosphere. Once developed, the pedosphere plays a significant role in supporting and maintaining life on the planet.
Copyright © 2006 by Taylor & Francis
It is obvious that soils will continue to be used to maintain and improve bioproductivity for food, feed, fuel, and fiber for a long time because the supply of elements and minerals necessary for life are derived, directly or indirectly, from soils. Healthy ecosystems and environments depend on soil-hosted microorganisms that facilitate filtering and purifying. There is still much to be learned about how soils behave in maintaining healthy anthropogenic landscapes. Unprecedented demands to safely handle wastes and provide major increases in food and feed are enormous challenges.[2,11] Perhaps less appreciated is the need of the human psyche for renewal through contact with nature. It appears that psychological well-being is, in part, related to our communion with the beauty, tranquility, and mysterious forces of nature. Although we are connected to the land and soils in ways that most of us do not readily comprehend, we do recognize the sense of belonging and the feeling of renewal associated with our contacts with the natural world. Is it a ‘‘dust thou art, and to dust thou shall return’’ syndrome in which our life cycle is subsumed in other natural life cycles? Whatever the explanation, the human-to-nature relationship is important, and soil is vital to our survival and growth.
Future of Soil Science: Role of Soils
CHANGING DEMOGRAPHICS It has been suggested that sometime in this century more than our entire current population will be living in cities.[12] As cities evolve into megacities through the use of adjacent lands, the unique culture of urban dwellers, including their estrangement from rural landscapes and ecosystems, also develops. Ecological functions of soils are common in extensive rural areas of the Earth, where the productive capacity of soils is easily recognized. In urban landscapes, which are very different in appearance, structure, and composition, the role of soils is commonly not observed, or even imagined, except in parks and residential lawns and gardens. Sewers and trash trucks remove numerous waste products, smoke stacks and vehicles exude particulates into the atmosphere, and streams and rivers wash away other debris. In rural landscapes, many of these functions are provided by the pedosphere—the covering of soils that seems to be ubiquitous and so common that it is taken-for-granted. How much relatively undisturbed land would be required to provide the energy and products consumed in an urban environment, and to adequately handle its wastes? Such a measure could be thought of as a city’s environmental footprint.[11] At present we do not measure and monitor the enormous fluxes that occur in urban environments, yet they are becoming major stressors on our global habitat.
INFLUENCING THE ROLE Is there a possibility of simply stretching current ecological theory to encompass urban ecosystems? It can be argued that our understanding of dynamics and processes of populations and soils can be extended to homeowners’ associations and pavement.[11] If people act as other organisms do, guided by individual self-interest, there is no basis for a moral or aesthetic
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call to environmental stewardship. Is there, perhaps, a spiritual or moral dimension that defies explanations offered by evolution or natural selection? The challenge of understanding urban ecosystems requires specialists from many different disciplines, but it also requires that at least some individuals think in interdisciplinary and multidisciplinary ways—a task that may be difficult to accomplish. The single most important force of landscape change in urban areas is land conversion driven by institutional decisions, population growth, and economic forces.[11] A city’s footprint, which indicates the dependence of an urban ecosystem on other ecosystems, may be tens or hundreds of times larger than the city itself. Soil ecosystems are being altered, and even created, to meet the expectations of urban communities. Consequently, the kinds and patterns of adjacent soil landscapes are important to the monitoring and assessment of environmental health and sustainability.[2,8]
THE FUTURE Humans have made tremendous achievements in their mutual adjustment to accepted standards.[13] For example, at a busy street corner clusters of pedestrians wait, voluntarily, for the light to change to green. When the light changes, surging individuals instinctively negotiate their way across the intersection, without bumping or colliding with those coming from the other direction. The voluntary acceptance of the established standard of traffic regulation by lights results in personal safety. The adaptive flexibility observed in this ‘‘uncentralized’’ operation[13] suggests how the balance of the soil functions will be solved in the future. A global consensus must develop that will clearly define a minimum set of common norms and international standards for sustainable uses of various kinds of soils. Knowledge about the limitations of specific kinds of soils for particular uses is essential for informed decisions and agricultural policies
Table 1 Soil attributes that can become future constraints to achieving desired balances of soil functions if excessive demands are placed on soil resources Soil attribute
Constraint
Resilience
Recovery from disturbance
Productivity
Capability for plant growth and yield
Responsiveness
Capacity for external enhancement
Sustainability
Dynamic equilibrium of interactions
Resistance
Stability to maintain current condition
Flexibility
Multiplicity of uses related to properties
Pedoclimate
Location and extent of suitable climate
Residence time
Capacity to store and release compounds
Geography
Availability due to location or intricacy of pattern
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(Table 1). For every conceivable use of soil there is a hypothetical ideal soil with the right set of properties and supporting processes to achieve a satisfactory level of success. Comparing local soils with a specified ‘‘ideal’’ soil can lead to recommended measures that minimize limitations and contribute toward attaining the expected behavior of such an ideal soil. When local economics of managing individual soils are considered, it is possible to develop rankings of suitability and economic feasibility. Understanding soil property–soil process relationships can provide a basis for creating and improving soil ecosystems needed to support the constantly changing global environment. International Organization for Standards (ISO), or something similar, will serve as universal ‘‘rules of the road.’’ Individuals and communities will adapt their actions and integration of needs with the available resources. Local flexibility will occur in the mutual adaptations applied to these global standards of ethical and environmental stewardship of the world’s natural resources. All these conditions can be achieved in, and by, the world’s diverse cultures through their own mutual adaptations. The future role of soils is truly in the hands and hearts of the people.
CONCLUSIONS Humanity has been overshooting the resource capacity of our Earth for several decades. There is great disparity among nations in their ecological footprints, thus the challenges of implementing practices to attain sustainability are many. Soils are vital to supplying food, feed, fiber, and fuel to support the development of future generations, consequently improved understanding of functions and limitations of local soils is relevant to helping meet the desires for resources and the handling of wastes in a sustainable global habitat for all humanity.
REFERENCES 1. Meadows, D.H.; Randers, J.; Meadows, D.L. Limits to Growth: The 30-year Update; Chelsea Green Publ. Co.: White River Junction, VT, 2004.
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2. Wackernagel, M.; Schulz, N.B.; Deumling, D.; Linares, A.C.; Jenkins, M.; Kapos, V.; Monfreda, C.; Loh, J.; Myers, N.; Norgaard, R.; Randers, J. Tracking the ecological overshoot of the human economy. Proc. Natl. Acad. Sci. (U.S.) 2002, 99 (14), 9266–9271. 3. Karlen, D.L.; Mausbach, M.J.; Doran, J.W.; Cline, R.G.; Harris, R.F.; Schuman, G.E. Soil quality: a concept, definition, and framework for evaluation. Soil Sci. Soc. Am. J. 1997, 61, 4–10. 4. De Soysa, I.; Gleditsch, N.P.; Gibson, M.; Sollenberg, M.; Westing, A.H. To Cultivate Peace: Agriculture in a World of Conflict; PRIO Report 1=99; International Peace Research Institute (PRIO): Oslo, 1999; 1–89. 5. Sokolov, I.A. Spatial–temporal organization of the pedosphere and its evolutionary and ecologic causes. Eurasian Soil Sci. 1994, 26 (4), 10–25. 6. Kovda, V.A. The Role and Functions of the Soil Cover in the Earth’s Biosphere; Scientific Center of Biological Research, Academy of Science, USSR: Pushchino, 1985; 1–12. 7. Targulian, V.O.; Rode, A.A.; Dmitriev, N.A.; Armand, A.D. Soil as a component of natural ecosystems and the study of its history, modern dynamics and anthropogenic changes. In Selection, Management and Utilization of Biosphere Reserves, Proceedings of the United States-Union of Soviet Socialist Republics Symposium on Biosphere Reserves, Moscow, USSR, May 1976; Franklin, J.F., Krugman, S.L., Eds.; USDA Pacific Northwest Forest and Range Experiment Station: Corvallis, Oregon, 1979; General Technical Report PNW 82, 186–197. 8. Millennium Ecosystem Assessment. Main findings; http:== www.greenfacts.org=ecosystems=millennium-assessment3199-main-findings.htm (accessed March 2005). 9. German Advisory Council on Global Change. World in Transition: The Threat To Soils; 1994, Annual Report; Economica Verlag: Bonn, 1995. 10. Yaalon, D.H.; Arnold, R.W. Attitudes toward soils and their societal relevance; then and now. Soil Sci. 2000, 165 (1), 5–12. 11. Collins, J.P.; Kinzig, A.; Grimm, N.B.; Fagan, W.F.; Hope, D.; Wu, J.; Borer, E.T. A new urban ecology. Am. Sci. 2000, 88 (5), 416–425. 12. Brown, L.R.; Gardner, G.; Halweil, B. Beyond Malthus: Sixteen Dimensions of the Population Problems; Worldwatch Paper 143; Worldwatch Institute: Washington, DC, 1998. 13. Cleveland, H. Coming soon: the nobody-in-charge society. Futurist 2000, 34 (5), 52–56.
Gas and Vapor Phase Transport Dennis E. Rolston University of California, Davis, California, U.S.A.
INTRODUCTION Diffusion is the principal mechanism in the interchange of gases between the soil and the atmosphere. The interchange results from concentration gradients established within soil by respiration of microorganisms and plant roots; by production of gases associated with biological reactions such as fermentation and nitrogen transformations; and by soil incorporation of materials such as fumigants, anhydrous ammonia, pesticides, and various volatile organic chemicals in toxic waste sites. The diffusion of water vapor within the soil also occurs due to differences in vapor pressure gradients induced by temperature differences or by evaporative conditions at the soil surface.
TRANSPORT PHYSICS AND EQUATIONS The diffusion velocities of gas mixtures in porous media are related to each other in a complex manner dependent upon the mole fraction of each gas, the molar fluxes of each gas, and the binary diffusion coefficient of each gas pair. If gravity effects are ignored or diffusion occurs only horizontally, the well-known Stefan–Maxwell equations provide the theoretical framework for diffusion of gases in soils. Fick’s law for diffusion is a restrictive case of the Stefan–Maxwell equations and is generally applicable for only a few special cases.[1] One of these cases is for the diffusion of a trace gas in a binary mixture, meaning that the mole fraction of the tracer gas is small. The second special case is for diffusion of two gases in a closed system (total pressure remains constant). In this case, neither gas needs to be in trace amounts. A third case where Fick’s law is applicable is for a three-component system where one of the gases exists in trace amounts and the binary diffusion coefficients of the other two pairs do not differ much from one another (basically the first case). Examples of this case would be for the gas pairs of N2–O2 and N2–Ar. Assuming that the special case conditions are met, Fick’s law is given by Mg dC g ¼ fg ¼ Dp At dx
ð1Þ
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-1-120042692 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
where Mg is the amount of gas diffusing (g gas), A is the cross-sectional area of the soil (m2 soil), t is time (sec), fg is the gas flux density (g gas=m2 soil=sec), Cg is concentration in the gaseous phase (g gas=m3 soil air), x is distance (m soil), and Dp is the soil-gas diffusion coefficient (m3 soil air=m soil=sec).
MEASUREMENT OF THE SOIL-GAS DIFFUSION COEFFICIENT The soil-gas diffusion coefficient, Dp, is the fundamental property that must be known to use Eq. (1) to calculate gas transport in soils. Values of Dp change with soil-air content and tortuosity (crookedness of the diffusion path). The standard laboratory method for measuring the soil-gas diffusion coefficient is based upon establishing gas concentration, Co, within a chamber (Fig. 1). One end of a soil core of concentration Cs is placed in contact with the gas within the chamber.[2] The other end of the soil core is maintained at concentration Cs. The gas of interest diffuses either into or out of the chamber depending upon the concentration Co compared to that outside the core. Obviously, the other gases making up the atmosphere will diffuse in an opposite direction to that of the gas of interest. The time rate of change of concentration in the chamber is related to the soil-gas diffusion coefficient and can be described by equations for unsteady diffusion of gas. Several investigators[2] have used similar procedures. The unsteady diffusion of a gas, which is nonreactive (physically, biologically, and chemically), is described by the combination of Fick’s first law [Eq. (1)] and the continuity equation (conservation of mass)
e
@Cg @ 2 Cg ¼ Dp @t @x2
ð2Þ
where e is the soil-air content (m3 air=m3 soil). In developing Eq. (2), it is assumed that the soil is uniform with respect to the diffusion coefficient and that e is constant in space and time. A simple solution of Eq. (2) that allows for the determination of Dp from laboratory measurements is available.[2,3] 745
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Gas and Vapor Phase Transport
(m3 voids=m3 soil), and b is the Campbell pore-size distribution parameter, corresponding to the slope of a plot of the log of the soil-water pressure potential vs. the log of the volumetric soil-water content. It has also been shown that there is a significant effect of macroporosity on Dp.[8] In this respect, macroporosity is defined as the air-filled porosity at a soil-water pressure head of –100 cm H2O (–10 kPa), corresponding to the volumetric content of soil pores with an equivalent pore diameter larger than 30 mm. The macroporosity (e100) is found by subtracting the volumetric soil-water content measured at a soil-water pressure head of –100 cm from the soil total porosity. Using this concept results in an additional equation 3 e 2þ3=b Dp ¼ 2e100 þ 0:04e100 D0 e100
Fig. 1 Schematic diagram of the apparatus design used for measuring the soil-gas diffusion coefficient of a soil core.
PREDICTIVE EQUATIONS FOR THE SOIL-GAS DIFFUSION COEFFICIENT Gas transport and fate simulation studies often depend on accurately estimating gas diffusivity (Dp=D0) as a function of soil-air content (e) from easily obtainable physical parameters of the soil, because measured data of Dp(e) are often not available. Many empirical models for predicting the gas diffusivity have been proposed, such as the well-known Millington–Quirk equation,[4] with varying degrees of prediction accuracy.[5] Recently, a series of papers[5–9] have offered new equations that appear to greatly increase the predictive accuracy. Separate equations are needed for undisturbed soils compared to sieved, repacked soils. To accurately predict diffusivity in undisturbed soils, the effects of texture and structure on the diffusivity must be considered.
Undisturbed Soil It has been shown that the Campbell[10] pore-size distribution (water retention) parameter, b, is an effective parameter to describe effects of soil type (soil texture and structure) on Dp(e) in undisturbed soils[5–8] to give e 2þ3=b Dp ¼ F2 D0 F
ð3Þ
where D0 is the gas diffusion coefficient in air (without soil) (m2 air=sec), F is soil total porosity
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ð4Þ
To summarize, Eq. (4) appears slightly more accurate and is recommended if both e100 and b are known, whereas Eq. (3) is recommended if only b is known. If the Campbell pore-size distribution parameter, b, is not measured, clay fraction is a good indicator of b,[11,12] and is given by b ¼ 13:6 CF þ 3:5
ð5Þ
Thus, Eq. (5) can be used to determine b to be subsequently used in either Eqs. (3) or (4).
Sieved, Repacked Soil Soil-type effects, such as texture and structure (manifested through pore-size distribution), on gas diffusivity in sieved and repacked soils appear to be minor and can likely be neglected.[9,13,14] A simple, physically based model[9] for Dp(e)=D0 in sieved and repacked soils is given by e Dp ¼ e1:5 D0 F
ð6Þ
The reduction term (e=F) describes the increased tortuosity in a wet soil, compared to a dry soil at the same soil-air content, because of interconnected water films. This equation has been shown to give accurate predictions of the soil-gas diffusion coefficient in sieved, repacked soil samples.[9]
CONCLUSIONS Although techniques for accurately measuring Dp in soil cores are now well established, measured data for Dp are often not available and predictive equations
Gas and Vapor Phase Transport
are required. It is now well established that equations needed to estimate Dp for undisturbed and for disturbed soil samples are indeed different. Equations for undisturbed soil must include soil-physical parameters that take into account the effects of soil type, such as texture, structure, and pore-size distribution, on Dp. Soil-type effects on Dp in sieved and repacked soils appear to be minor.
ARTICLES OF FURTHER INTEREST Aeration Measurement, p. 33. Aeration: Tillage Effects, p. 36. Air Permeability of Soils, p. 60. Greenhouse Gas Fluxes: Measurement, p. 787. Nitrous Oxide Emissions: Agricultural Soils, p. 1129. Nitrous Oxide Emissions: Sources, Sinks, and Strategies, p. 1133. Oxygen Diffusion Rate and Plant Growth, p. 1236. Tillage and Gas Exchange, p. 1773.
REFERENCES 1. Amali, S.; Rolston, D.E. Theoretical investigation of multicomponent volatile organic vapor diffusion: steady-state fluxes. J. Environ. Qual. 1993, 22, 825. 2. Rolston, D.E.; Moldrup, P. Gas diffusivity. In Methods of Soil Analysis, Part 4. Physical Methods; Dane, J.H., Topp, G.C., Eds.; Agronomy Monograph No. 9; Soil Science Society of America: Madison, 2002; 1113. 3. Currie, J.A. Gaseous diffusion in porous media. Part 1. A non-steady state method. Br. J. Appl. Phys. 1960, 11, 314.
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4. Millington, R.J.; Quirk, J.M. Permeability of porous solids. Trans. Faraday Soc. 1961, 57, 1200. 5. Moldrup, P.; Kruse, C.W.; Rolston, D.E.; Yamaguchi, T. Modeling diffusion and reaction in soils. III. Predicting gas diffusivity from the Campbell soil-water retention model. Soil Sci. 1996, 161, 366. 6. Moldrup, P.; Olesen, T.; Rolston, D.E.; Yamaguchi, T. Modeling diffusion and reaction in soils. VII. Predicting gas and ion diffusivity in undisturbed and sieved soils. Soil Sci. 1997, 162, 632. 7. Moldrup, P.; Olesen, T.; Yamaguchi, T.; Schjønning, P.; Rolston, D.E. Modeling diffusion and reaction in soils. IX. The Buckingham–Burdine–Campbell equation for gas diffusivity in undisturbed soil. Soil Sci. 1999, 164, 542. 8. Moldrup, P.; Olesen, T.; Schjønning, P.; Yamaguchi, T.; Rolston, D.E. Predicting the gas diffusion coefficient in undisturbed soil from soil water characteristics. Soil Sci. Soc. Am. J. 2000, 64, 94. 9. Moldrup, P.; Olesen, T.; Gamst, J.; Schjønning, P.; Yamaguchi, T.; Rolston, D.E. Predicting the gas diffusion coefficient in repacked soil: water-induced linear reduction model. Soil Sci. Soc. Am. J. 2000, 64, 1588. 10. Campbell, G.S. A simple method for determining unsaturated conductivity from moisture retention data. Soil Sci. 1974, 117, 311. 11. Clapp, R.B.; Hornberger, G.M. Empirical equations for some soil hydraulic properties. Water Resour. Res. 1978, 14, 601. 12. Olesen, T.; Moldrup, P.; Henriksen, K.; Petersen, L.W. Modeling diffusion and reaction in soils. IV. New models for predicting ion diffusivity. Soil Sci. 1996, 161, 633. 13. Xu, X.; Nieber, J.L.; Gupta, S.C. Compaction effects on the gas diffusion coefficient in soils. Soil Sci. Soc. Am. J. 1992, 56, 1743. 14. Jin, Y.; Jury, W.A. Characterizing the dependency of gas diffusion coefficient on soil properties. Soil Sci. Soc. Am. J. 1996, 60, 66.
Gelisols James G. Bockheim University of Wisconsin, Madison, Wisconsin, U.S.A.
INTRODUCTION Gelisols, the permafrost-affected soils, comprise 18 million square kilometer or about 13% of the earth’s land surface. They occur in polar regions, the Arctic and Antarctic, and in a few alpine regions (Fig. 1). Gelisols are of global concern because they contain many protected areas and support indigenous people who depend on the land and the surrounding oceans for sustenance. They may be subject to considerable impacts from human development (oil, coal, gas, and gas hydrite exploitation), and are already experiencing global warming.[1] Gelisols have permafrost within 100 cm of the soil surface, or gelic materials within 100 cm of the surface and permafrost within 200 cm of the surface.[2] Permafrost is commonly defined as an earthy material that remains at temperatures below 0 C for two or more years in succession; it may be ice-cemented or, in the case of insufficient interstitial water, dry-frozen. The zone above permafrost that is subject to seasonal thawing is known as the active layer. Gelic materials are defined as seasonally or perennially frozen minerals or organic soil materials that have evidence of cryoturbation (frost churning), ice segregation, or cracking from cryodesiccation.
THE PEDON AS A BASIC SOIL UNIT FOR GELISOLS The pedon is the basic soil unit for sampling in ‘‘Soil Taxonomy,’’[2] and is especially important for describing, classifying, and sampling Gelisols, which often occur in areas with patterned ground. Patterned ground is a general term for any ground surface that is ordered into polygons, nets, circles, or stripes as a result of freezing and thawing processes. Fig. 1 shows earth hummocks in an alpine region resulting from such processes. Each hummock is 1–1.5 m across and is about 1 m high. The pedon is defined so as to encompass the full cycle of patterned ground with a 2 m linear interval or a half cycle with a 2–7 m cycle. This interval is suitable for most patterned ground features such as earth hummocks. In the case of large-scale (>7 m) patterned ground, such as ice-rich, low-center polygons, 748 Copyright © 2006 by Taylor & Francis
two pedons are established: one within the center of the polygon and the other within the trough containing an ice wedge. Therefore, each hummock in the figure represents a single pedon for descriptive and sampling purposes.
CLASSIFICATION OF GELISOLS There are three suborders within the gelisol order, which include histels, turbels, and orthels. They are distinguished on the basis of organic matter content and mineral soils, whether or not there is evidence for cryoturbation. Histels have 80% or more organic materials by volume within the upper 50 cm or to a restricting layer. They are subdivided into five great groups based on the nature of the underlying material and the degree of decomposition: glacistels, folistels, fibristels, hemistels, and sapristels.[3] The glacistel illustrated in Fig. 2 contains 60 cm of organic material directly overlying ground ice. Disturbance to the surface-insulating layer may cause the ice layer to melt and the soil to collapse, a condition known as thermokarst (Fig. 3). The key properties of histels are abundant organic materials ranging from woody to highly decomposed materials, a high moisture holding capacity, and a pH that for an array of histels may range from as low as 2.5 to above 7.0. Although histels comprise less than 3% of the Gelisols globally, they cover large areas in North America and Russia. Turbels represent a second suborder of the gelisols; they are mineral soils subject to cryoturbation. Turbels comprise about 87% of the gelisols on a global basis. Cryoturbation is evidenced by irregular or broken horizons, involutions, organic matter accumulated on the surface of the permafrost, oriented rock fragments, and silt coatings and silt-enriched subsoil horizons that result from freezing and thawing, frost heaving, and cryogenic sorting.[4] Cryoturbation is caused primarily by differential frost heave, but its action can be enhanced by cryostatic pressure, differential swelling, and load casting on poorly drained sites.[5] Fig. 4 shows an aquiturbel on earth hummocks (see also Fig. 1) in northern Canada. This pedon contains an organic layer along the rim of the earth hummocks Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042693 Copyright # 2006 by Taylor & Francis. All rights reserved.
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Fig. 3 This landform in the Russian far east contains abundant ground ice that has melted following disturbance of the surface organic materials, resulting in a condition known as thermokarst. Fig. 1 Earth hummocks, a type of patterned ground, in the North Cascades of Washington State, U.S.A. Each hummock is 1–1.5 m wide and about 1 m high. This landform features a type of soil known as turbels.
and intensely cryoturbated mineral soil horizons in the center. Although the underlying concept of turbels is that they are subject to cryoturbation, they may contain diagnostic horizons that are common to soils not having permafrost recognized at the great group level. There are seven great groups within the turbels (histoturbels, aquiturbels, anhyturbels, molliturbels, umbriturbels, psammoturbels, and haploturbels) that link them with other soils that do not contain permafrost.[2] It should be emphasized that cryopedogenic processes such as cryoturbation, thermal cracking,
Fig. 2 A hemic glacistel in northern Canada. The organic soil materials, which are intermediate in decomposition from fibric (peat) and sapric (muck), are underlain by ground ice at 60 cm.
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and ice segregation are soil-forming processes characteristic of soils with permafrost. They should not be viewed as operating against the other soilforming processes in low-latitude soils; rather, they are distinctive processes producing horizons and properties that are uncommon to other soil orders. Processes common to the other soil orders do operate in gelisols, but at a lesser magnitude, because of the dominance of cryopedogenic processes. The third suborder within the gelisols is the orthels, which include other mineral soils containing permafrost within the upper 100 cm. These soils comprise about 10% of the gelisols globally. The orthels are subdivided into eight great groups that are more or less parallel to those in the turbels and link them to soils not containing permafrost (historthels, aquorthels,
Fig. 4 An aquiturbel developed on an earth hummock in northern Canada (see also Fig. 1).
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Fig. 6 An apartment complex in the upper Kolyma River region of the Russian Far East that is built on stilts to avoid heat transfer, melting of permafrost, and subsidence.
CONCLUSIONS
Fig. 5 A spodic psammorthel in northern Russia. The soil is excessively drained, developed in sandy floodplain deposits, and contains weakly developed spodic materials in the upper part. (Photo provided by L. Huber.)
anhyorthels, mollorthels, umbrorthels, argiorthels, psammorthels, and haplorthels). Fig. 5 shows a spodic psammorthel in northern Russia. The soil is derived from sandy floodplain deposits and contains weakly developed spodic materials.
GELISOLS AND LAND USE Gelisols offer special challenges to land management for interpretation and practices, including construction (structures and pipelines), mining, forestry, and agriculture. For example, structures must be built on refrigerated pilings or above ground (Fig. 6), so that heat from the structure does not melt the permafrost and cause subsidence. A main concern with gelisols is that they are large C sinks (Table 1). The concern is that warming in the Arctic could increase the thickness of the seasonal thaw layer and enhance heterotrophic respiration, releasing additional CO2 into the atmosphere. In this case, gelisols would become a C source.
Copyright © 2006 by Taylor & Francis
Gelisols occur primarily in the Polar Regions and are soils containing permafrost within 100 cm of the soil surface, or gelic materials within 100 cm and permafrost within 200 cm of the surface. Gelisols originate from cryopedogenic processes that include cryoturbation, freezing and thawing, cryogenic sorting, ice segregation, and cryodesiccation. The low temperatures in gelisols give rise to cryostatic pressure development and migration of water with resultant ice buildup. Therefore, gelisols are differentiated from other soils
Table 1 Carbon storage in two gelisols Horizon
Depth (cm)
Organic C (%)
Bulk density C storage (kg/m3) (g/cm3)
Pedon A96-29: typic aquiturbel; Barrow, Alaska[6] Oi 1 25.3 0.42 Bg 32 9.9 1.05 Oejj 2 18.8 0.38 Bgf 15 7.3 0.83 BCgf 12 3.9 1.05 Cgf 38 4.4 1.02
1.1 33.3 1.4 9.1 4.9 17.1
Total
66.9
Pedon 94P0668: typic molliorthel; lower Kolyma River, Russian Far East[2] A 7 7.5 1.04 5.5 AB 5 0.65 1.65 0.5 Bw1 26 0.56 2.4 Bw2 21 0.48 1.7 Bw3 19 0.44 1.66 1.4 Bw4 16 0.44 1.79 1.3 Cf 6 0.39 0.4 Total
13.2
Gelisols
primarily on the basis of thermal characteristics and physical properties that are readily observed in the field. The three main types of gelisols are histels (organic soils with permafrost), turbels (mineral soils with cryoturbation), and orthels (other mineral soils with permafrost in the upper 100 cm). The pedon concept is especially important for sampling gelisols, and is determined by the size of the repeating units of patterned ground features, e.g., 7 m.
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2.
3. 4.
5.
REFERENCES 1. Bockheim, J.G.; Ping, C.L.; Moore, J.P.; Kimble, J.M. Gelisols: a new proposed order for permafrost-affected soils. Proceedings of the Meeting on the Classification, Correlation, and Management of Permafrost-Affected Soils, Fairbanks, Alaska; Kimble, J.M., Ahrens, R.J.,
Copyright © 2006 by Taylor & Francis
6.
Eds.; USDA, Soil Conservation Service, National Soil Survey Center: Lincoln, NE, 1994; 25–44. Soil survey staff. Soil Taxonomy: A Basis System of Soil Classification for Making and Interpreting Soil Surveys, 2nd Ed.; USDA Natural Resources Conservation Service. Agric. Handbook No.436; U.S. Government Printing Office: Washington, DC, 1999. Soil survey staff. Keys to Soil Taxonomy, 9th Ed.; USDA Natural Resources Conservation Service, 2003. Bockheim, J.G.; Tarnocai, C. Recognition of cryoturbation for classifying permafrost-affected soils. Soil Sci. 1998, 162, 927–939. Van Vliet-Lanoe, B. Differential frost heave, load casting and convection: converging mechanisms; a discussion of the origin of cryoturbations. Perm. Periglac. Proc. 1991, 2, 123–139. Bockheim, J.G.; Everett, L.R.; Hinkel, K.M.; Nelson, F.E.; Brown, J. Soil organic carbon storage and distribution in Arctic Tundra, Barrow, Alaska. Soil Sci. Soc. Am. J. 1999, 63, 934–940.
Geology and Soil Ken R. Olson University of Illinois, Urbana, Illinois, U.S.A.
INTRODUCTION Geology is the study of Earth, its internal structure, its materials, its chemical and physical processes, and its physical and biological history.[1] One of the most important geological discoveries was that rocks could form by crystallization of molten material. Rocks do change from one kind to another. As rocks get exposed to the surface weather, particles move downstream, eventually to be deposited as sediments that lithify into sedimentary rocks. By tracing distributions of rock materials, early geologists were able to link sediments to highly consolidated, mineralogically distinct metamorphic rocks.
ATMOSPHERE, HYDROSPHERE, AND LITHOSPHERE The crust, mantle, and core account for 99.97% of the mass of the Earth.[1] The lithosphere includes the Earth’s crust and upper mantle. The term has previously been used to describe the entire portion of the Earth that is composed of rocks. The remaining 0.03% comprises the atmosphere and the hydrosphere. The hydrosphere includes the portion of the Earth’s surface that is covered by water. The hydrosphere behaves as an intermediate reservoir for carbonates, silicates, and other mineral groups leached from the rock of the continents and carried to the oceans by rivers.[1] Both silicates and calcium carbonate follow involved paths from the time they are weathered from continental rock, until they are deposited on the sea floor. The composition of the atmosphere is strongly influenced by the cycling of water from the oceans to the continents, and by its return to the oceans in rivers and subsurface flow. The amount of free oxygen in the atmosphere seems to remain essentially constant. Volcanic gases contain only traces of molecular oxygen but eject large quantities of molecular hydrogen, carbon monoxide, and sulfur dioxide. These gases react with atmospheric oxygen to produce carbon dioxide, water vapor, and sulfur dioxide. The lithosphere, which consumes free oxygen through weathering of rock, and the biosphere, which produces oxygen through photosynthesis, maintain this equilibrium. 752 Copyright © 2006 by Taylor & Francis
The control over this equilibrium may be a feedback mechanism involving the organisms whose by-products and remains become constituents of sedimentary rock.
CYCLING OF ELEMENTS Oxygen, silicon, aluminum, and iron contribute 96% by volume of the elemental composition of the Earth’s crust.[2] The other elements only occupy the remaining 4%. Individual atoms or molecules of such elements such as carbon, nitrogen, oxygen, and sodium change form countless times as they cycle through the atmosphere, biosphere, and lithosphere.[1] Oxygen, for instance, may be converted from a neutral atom to dissolved gas, from combined molecule to ionized particle, to protoplasmic components, and, perhaps, back to the ionic state as a constituent of rock.[1] Other atoms, such as sodium or silicon, may be more constrained in the variety of chemical forms they may assume. These and other representative routes are indicated in a revised and modified schematic shown in Fig. 1.
CHEMICAL WEATHERING PROCESSES ‘‘Weathering’’ is a collective term for the combined effects of all the physical and chemical processes that break down and transform pre-existing rock materials near the Earth’s surface to products that are more stable under the physical and chemical conditions at the surface. Weathering constitutes the response of rock materials to several forms of energy as a function of time.[1] The products of weathering include solids (i.e., sediments and soils) and liquids (including the solutions of salts present in rivers and the ocean). Each physical and chemical factor of weathering affects the outcome of the weathering process. These factors and related variables of the rock cycle, including erosion, transportation, and sedimentation, combine to operate as a complex chemical sorting system which distributes products of different composition to various sites of deposition. Soils are the result of leaching, oxidation, and dissolution of surface materials by the percolation of groundwater and by humic acids derived from oxidized Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042694 Copyright # 2006 by Taylor & Francis. All rights reserved.
Geology and Soil
Fig. 1 Cycling of elements. (From Ref.[1].)
organic materials. New minerals, such as clays, are formed by the chemical alteration of the original mineral of the bedrock.[1] The chemical weathering process develops a soil profile ranging from heavily weathered surface materials down to unaltered rock. The soil zone is the zone of transition between solid rock and the atmosphere. The solid rock, or bedrock, usually has numerous tiny cracks or joints. Chemical weathering caused by water, which fills the cracks, attacks the joints’ surfaces and enlarges the cracks.
PARENT MATERIAL Parent material is the initial or starting material from which a soil develops. This initial material can include either consolidated rock or unconsolidated material deposited by gravity, wind, or water and consists of specific minerals of different sizes, or even plant materials of various plant types.[2] Mineral matter inherited from rocks is referred to as soil parent material because it is the principal ingredient from which soils are formed.[3] However, the principal parent materials of organic soils are decomposing plants. In many cases, relief prior to and during soil formation is related to the nature of the initial soil material.
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In broad river deltas, crests of natural levees near the stream channels have more coarse material than the areas beyond the levees that are nearly level, and have the finer textured initial material.[4] In steeper topography, where the valleys below the mountain ranges are characterized by broad alluvial–colluvial fans, the initial material near the mountain range contains more coarse and angular material than areas farther away from the mountain range.[5] After unconsolidated parent material is deposited on a stable landscape, or after bedrock has been exposed at the Earth’s surface, soil formation begins and continues over time. The rate of soil formation depends on the climate, including temperature and rainfall. It also depends on vegetation and the activity of other organisms, which live on or in the parent material. These organisms help convert parent materials to soil. Russian pedologists[6] identified parent material as one of the five significant soil-forming factors. Early approaches to soil survey and classification were based on the geology and composition of the soil-forming material.[7,8] The geologic origin and composition of the initial material was identified by the terms ‘‘Agranite soils’’ or ‘‘Aglacial soils.’’ Soils that originate from a parent material inherit the mineral types found in them. Over time, these original minerals are weathered (dissolved) and new minerals form and accumulate in the soils.[2] Russian soil scientists[9] showed the controlling effects of parent material on soil properties. Jenny[10] conducted a systematic analysis of the relationship between soil properties and parent materials from which the soils developed. Jenny proposed parent materials as an independent soil-forming factor, defining parent material as ‘‘the state of the soil system at time zero of soil formation.’’ The physical body of soil and its associated mineralogical and chemical properties are the starting point for the interaction of other soil-forming factors. Previous weathered rock—even a previous soil—could be considered as parent material. The properties of modern soil are the result of the composition of the surficial layer, which existed when the other factors started to impact, and the alterations resulting from the effect of these factors over time. Properties of younger soils are greatly influenced by parent material. Weathering and pedogenic processes result in characteristics of the original parent material being eliminated. Extremely resistant initial material, such as quartz or sand, may still exist in old, weathered soils. It can be difficult to separate the nature (or characteristics) of the initial material and its influence on soil, the kind of ‘‘preweathering’’ of the initial material before becoming parent material for the soil, and the effects of the other soil-forming factors on the parent
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material of this soil. The complex environmental history (climatic and vegetation changes in the recent geologic past) makes it difficult to separate parent material influences on soil properties from other factor effects. Rock types influence the soil properties of the modern soil. The impact of rock type on soil properties was organized by Buol, Hole, and Mc Craken[11] into the following subdivisions: sedimentary, igneous, and combinations of mineralogically similar metamorphic and igneous rocks. Sedimentary rocks include unconsolidated glacial deposits, loessial deposits, unconsolidated coastal plain sediments, and consolidated rock, such as limestone and dolomites, sandstones, and shales. Siliceous crystalline rocks include more ‘‘acidic’’ quartzose, igneous, and metamorphic rocks including granites, granite gneiss, and schists. Dark-colored ferromagnesian rocks include andosites, diorites, basalt, and hornblende gneiss. Volcanic ash parent materials are composed of noncrystalline materials, any glass fragments, bits of the easily weatherable feldspars, ferromagnesian minerals, and varying amounts of quartz. Mineral components of many soils are inherited almost exclusively from parent materials, while others are developed mostly in situ during the course of weathering and pedogenesis. Primary minerals are formed at high temperature in igneous and metamorphic rocks. Secondary minerals are formed at lower temperature in sedimentary rocks and soils.[12]
CONCLUSIONS The basic model of soil implies that soils are dynamic and geographical. In soil systems, the processes or driving forces are best described as dynamic, rather than static. Morphological properties of soil are the result of processes acting on parent materials. In addressing the influence of parent materials in soil genesis, Chesworth[13,14] stated that ‘‘time has the result of modifying
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Geology and Soil
the parent material effects so that only in young or relatively immature soils will the parent material exert its strongest influence on the soil-forming process. That influence will be an inverse function of time.’’
REFERENCES 1. Jackson, C. Geology Today; CRM Books, Communications Research Machines: Del Mar, CA, 1973. 2. Singer, M.J.; Munns, D.N. Soils, An Introduction, 3rd Ed.; Prentice Hall: Upper Saddle River, NJ, 1996. 3. Troeh, F.R.; Thompson, L.M. Soils and Soil Fertility, 5th Ed.; Oxford University Press: New York, 1993. 4. Russell, R.J. River Plains and Sea Coasts; University of California Press: Berkeley, 1967. 5. Birot, P. The Cycle of Erosion in Different Climates; Translated by Jackson, C.I., Clayton, K.M., Eds.; University of California Press: Berkeley, 1960. 6. Dokuchaev, V.V. Russian Chernozem (Russkii Chernozen). In Collected Writings (Sochineniya); Academy of Science: Moscow, USSR, 1883; Vol. 3. 7. von Richthofen, F.F. Fuhrer fur Forschungsreisende; (cited in Joffe, J.S., 1936: Pedology, Rutgers University press, New Brunswick, N.J), 1886. 8. Thaer, A.D. Grundsatze der Rationaellen Landwirtschaft (cited in Joffe, J.S., 1949: Pedology Publ., New Brunswick, NJ), 1809, 1810, 1812; Vol. 1–4. 9. Polynov, B.B. Das Muttergestein als Faktor de Bodenbildung und als Kriterium fur die Bodenklassification. Soil Res. 1930, 2, 165–180. 10. Jenny, H. Factors of Soil Formation; McGraw-Hill: New York, 1941. 11. Buol, S.W.; Hole, F.D.; Mc Cracken, R.J. Soil Genesis and Classification, 2nd Ed.; The Iowa State University Press: Ames, 1980. 12. Jackson, M.L. Chemical composition of soils. In Chemistry of Soil, 2nd Ed.; Bear, F.E., Ed.; Reinhold: New York, 1964. 13. Chesworth, W. The parent rock effect in the genesis of soil. Geoderma 1973, 10, 215–225. 14. Chesworth, W. Conceptual models in pedogenesis: a rejoinder. Geoderma 1976, 16, 257–260.
Geophysics in Soil Science Jeffrey J. Daniels Department of Geological Sciences, The Ohio State University, Columbus, Ohio, U.S.A.
Barry Allred Fdag&Bioen, United States Department of Agriculture (USDA), Columbus, Ohio, U.S.A.
Mary Collins Soil and Water Science Department, University of Florida, Gainesville, Florida, U.S.A.
James Doolittle United States Department of Agriculture (USDA), Newtown Square, Pennsylvania, U.S.A.
INTRODUCTION Geophysics can be defined as the science of measuring physical property changes in the subsurface through the use of instruments located in boreholes, on (or near) the surface, or in the air. The instruments that make these measurements are designed to detect a particular phenomenon caused by a contrast in physical properties. In some cases, there is a source of energy that stimulates a detectable physical change in the subsurface that can be detected by some type of detector that is separate from the source of energy. These methods are called active measurements. Other measurements simply detect a change in the natural background, and these methods are called passive measurements. Geophysical methods can be further classified based on the general category of physical properties that are measured. The general classification includes electrical, seismic, nuclear, potential field, and thermal methods. Detailed summaries of the operational principles of these methods are given in a number of texts in Refs.[1,2].
GEOPHYSICS APPLIED TO SOIL SCIENCE The application of geophysical methods for agricultural purposes has been steadily growing over the past two decades. The impetus for these developments has been the primary need to improve the efficiency of agricultural processes. These improvements have required an increase in the knowledge of the physical and chemical properties at a given field site. The physical properties of interest include the soil texture, moisture, and density, and the location of tiles and drains in the subsurface. The chemical properties of interest include soluble salts, nutrients, and cationexchange capacity of soils. Electrical and neutron Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120006627 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
scattering were proven to be the most effective methods in addressing these problems. There are numerous electrical methods, with each method measuring a specific electrical parameter that changes as a function of distribution of electrical permittivity (e), conductivity (s), or magnetic per meability (m) in the subsurface. A summary of the geophysical methods that have been used for the purpose of analyzing the physical and chemical properties of soil are presented in Table 1. The last column lists the soil property that is most commonly the objective of the method. However, other physical and chemical properties will influence the measurement. Electrical Resistivity (Conductivity) The electrical resistivity response (which is the inverse of electrical conductivity) that is measured in soil is affected by a number of different soil characteristics including particle-size distribution, clay mineralogy, cation-exchange capacity, salinity, plant nutrients, moisture content, etc. Therefore soil electrical conductivity mapping can provide indications of spatial trends in these soil characteristics. In the traditional electrical resistivity method, an electrical current is supplied between two electrodes staked into the ground while voltage is concurrently measured between one or more separate pairs of staked electrodes. The method is slow and tedious. Newer technologies with pulled electrode arrays[3] capable of continuous electrical resistivity measurement have made it easier to measure resistivity in the field. One field version of a soil electrical conductivity system was developed by Veris Technologies. This soil electrical conductivity mapping system utilizes direct-contact pulled coulter-electrode resistivity arrays. The OhmMapper TR1 is another resistivity system that is designed for rapid data acquisition. It is a capacitively 755
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Table 1 Summary of geophysical methods applied to soil analysis problems Method Direct current resistivity
General description Measures variations in subsurface conductivity by measuring the resistance to the flow of direct current.
Frequency range (electrical only)
Soil properties primarily analyzed
0 Hz
Texture
Moisture Induction electromagnetics (EM)
Measures variations in subsurface conductivity by measuring the secondary electromagnetic fields that are induced by low-frequency electromagnetic signal. Induced magnetic and electric fields are both measured.
100 Hz–100 kHz
Texture
Moisture Ground-penetrating radar (GPR)
Measures the propagation (reflection, diffraction, refraction) of a high-frequency electromagnetic wave as a function of travel time.
10 MHz–5 GHz
Texture
Moisture Density Conductivity probe
Measures the electrical conductivity with a probe inserted into the ground.
Moisture Texture
Time domain reflectometry (TDR)
Measures the velocity of a high-frequency electromagnetic wave.
10–100 MHz
Moisture
Neutron–neutron (NS)
Measures the thermal absorption and scattering of thermal neutrons
NA
Moisture Density
coupled resistivity measurement system that operates as a towed dipole–dipole electrode array with continuous data collection. The array is connected to a data logger console and can be integrated with Global Positioning Systems (GPS) while being towed by a person or vehicle. Changing the separation distance between the two dipoles within the array alters the depth of measurement. This capability allows the versatility to produce horizontal maps or vertical profiles of the interpreted electrical conductivity (or resistivity). Photographs of the Vertis and OhmMapper systems are shown in Fig. 1, along with a cross-section profile line of data from the OhmMapper system.
Electromagnetic Induction Electromagnetic induction typically employs an instrument referred to as a ground conductivity meter (GCM). An alternating electrical current is passed through one of two small electric wire coils spaced a set distance apart and housed within the GCM. One coil generates an electromagnetic (EM) field above the surface, inducing a secondary electromagnetic field that propagates into the ground. The second wire coil acts as a receiver measuring the amplitude and phase
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components of the fields after they propagate through the ground and is used to calculate an ‘‘apparent’’ value for soil electrical conductivity. Several factors influence the measured response including the primary (instrument) field frequency, and the soil moisture conditions, clay content, and soluble salt contents. The primary advantage of induction methods is that direct contact with the ground is unnecessary. Therefore the method can be used to rapidly acquire measurements of the near-surface conductivity. Electrical Conductivity Probes A variety of hand-operated or machine-powered push probes are available for obtaining point values of electrical conductivity at different depths within the soil profile. Often, these probes contain more than one sensor so that other soil characteristics, such as temperature and penetration resistance, can likewise be measured. Ground-Penetrating Radar Ground-penetrating radar (commonly called GPR) is a high-resolution electromagnetic technique that is primarily designed to investigate the shallow subsurface
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Fig. 1 Veris 3100 Soil EC Mapping System pulled resistivity array, Ohm apper TR1 vertical resistivity (O m) system, and an interpreted apparent resistivity profile from a test plot located on the Ohio State University Waterman Agricultural and Natural Resources Laboratory in Columbus, Ohio.
of the earth, building materials, and roads and bridges. It is a time-dependent geophysical technique that can provide a 3-D pseudo image of the subsurface, including the fourth dimension of color, and can also provide accurate depth estimates for many common subsurface features. This technology was proven capable of delineating soil profile layers[4] and also shows great promise with regard to updating soil survey information.[5] The radar was used to document the type and variability of soils that occurred in a soil map unit.[6] Collins[7] and Doolittle and Collins[8] demonstrated how soil information can be used as a guide to determine applicability of GPR at a field site and the criteria used to define and classify soils from radar imagery. Today’s GPR technology allows us to model the subsoil in 3-D and geo-reference the data with GPS. Tischler, Collins, and Grunwald[9] demonstrated how GPR data can be incorporated into ArcView and ArcGIS software to create models with GPR and GPS data that show soil subsurface features such as sandy horizons over an argillic (high in clay) horizon.
The details of field data measurement procedures vary from site to site; however, most GPR field measurements are initially displayed in the form of a two-dimensional cross section that is similar to a seismic section (Fig. 2). If the velocity of the electromagnetic wave is known, then a GPR cross section in Fig. 2 can be interpreted as a depth–distance cross section of the subsurface. The two-dimensional cross sections (Fig. 2) provide good information concerning the stratigraphy at a site and the location of the water table, while a threedimensional display can be constructed of closely spaced two-dimensional lines.[10] An example of a GPR amplitude map from a depth interval of 0.7 to 1.2 m (2.3–4 ft) is shown in Fig. 3. The lighter shades on the grayscale map represent locations where a greater amount of reflected radar energy returned to the surface. Locations showing greater reflected radar energy represent dielectric constant discontinuities in the subsurface and often indicate the existence of buried objects. Where there are mapped linear trends
Fig. 2 Examples of applications of GPR field measurements.
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Fig. 3 GPR amplitude map for depth interval of 0.7–1.2 m showing subsurface drainage system.
Geophysics in Soil Science
environment are associated with water. Neutron probes used for soil moisture measurement emit highenergy neutrons (5 MeV) from a radioactive source, such as radium–beryllium or americium–beryllium. The neutron probes used for agricultural purposes are lowered through the soil profile within boreholes lined with aluminum, steel, or plastic access tubing. When the probe is lowered to measure soil moisture content at a particular depth, the constant emission of high-energy neutrons quickly produces an equilibrium cloud of thermal neutrons surrounding the borehole at that location. The density of this cloud of thermal neutrons depends on the amount of water present in the soil at this depth. The greater the density of the thermal neutron cloud, the greater the amount of water present. Therefore sensors on the probe capable of counting thermal neutrons provide information on soil moisture content at different depths beneath the surface.
of high radar amplitude (energy), subsurface drainage pipes may be present, as shown on this map. CONCLUSIONS Time Domain Reflectometry Time domain reflectometry (TDR) is a high-frequency electromagnetic analysis technique described by Topp, Davis, and Annan[11] The TDR method is based on the fact that the relative electric permittivity (e) of any material is related to the velocity of a high-frequency electromagnetic signal by the relationship: V0 Vm ¼ pffiffi e where V0 and Vm are the velocities of the electromagnetic wave through air and the material, respectively. The relative electric permittivity is equal to the ratio of electric permittivity of the material to the electric permittivity of air (free space). The relative electric permittivity values range from 1 to 81, with a value of 1 being the relative permittivity of air, and 81 being the relative permittivity of water. Hence water is the single most important factor that affects the permittivity of soil. Therefore a measure of velocity of a highfrequency electromagnetic wave can be indirectly used to measure the moisture of soil. Hand-held TDR probes that take electromagnetic pulse travel time measurements and then automatically calculate soil volumetric water content are now readily available. Neutron–Neutron Hydrogen nuclei have a strong capacity for scattering and slowing neutrons. This characteristic can be utilized to measure volumetric moisture content because most of the hydrogen atoms found in the soil
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Geophysical methods are important noninvasive tools for determining the physical properties of soil. Electrical and neutron–neutron (NS) methods were demonstrated to be useful in determining soil moisture and in classifying soils. Ground-penetrating radar is a technique that can be used to map soil horizons, bedrock, stratigraphic layers and cultural features (e.g., field tile) in the subsurface. Geophysical methods can be used to rapidly evaluate the conditions of the subsurface over large areas. Geophysical methods have been applied to problems in determining the moisture of soil in the near surface by inserting probes into the ground. The primary methods include the following: 1) neutron–neutron (sometimes called neutron scattering; or NS); 2) time domain reflectometry (TDR); and 3) capacitance measurements. Each of these measurements employs a different physical principle to estimate moisture. All geophysical methods must be calibrated for local conditions, and assume a fairly uniform distribution of the mineralogy throughout the volume that is being analyzed.
REFERENCES 1. Reynolds, J.M. An introduction to applied and environmental geophysics. In Geophysical Methods; Sheriff, R.E., Ed.; Prentice Hall, Wiley: New York, 1989. 2. Sheriff, R.E. Geophysical Methods; Prentice Hall: New York, 1989; 605 pp. 3. Sorensen, K. Pulled array continuous electrical profiling. First Break 1996, 14 (3), 85–90. 4. Kung, K.-J.S.; Boil, J.; Selker, J.S.; Ritter, W.F.; Steenhuis, T.S. Use of ground penetrating radar to
Geophysics in Soil Science
improve water quality monitoring in the vadose zone. In Preferential Flow; Gish, T.J., Shirmohammadi, A., Eds.; ASAE: St. Joseph, MI, 1991; 142–149. 5. Schellentrager, G.W.; Calhoun, T.E.; Doolittle, J.A.; Wettstein, C.A. Using ground penetrating radar to update soil survey information. Soil Sci. Soc. Am. J. 1988, 52 (3), 746–752. 6. Doolittle, J.A.; Schellentrager, G.W. Soil Survey of Orange County, Florida. USDA-SCS; U.S. Government Printing Office: Washington, DC, 1989. 7. Collins, M.E. Soil taxonomy: a useful guide for the application of ground-penetrating radar. 4th International Conference on Ground Penetrating Radar, 1992; Geological Survey of Finland, 1992; 125–132; Special Paper 16.
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8. Doolittle, J.A.; Collins, M.E. Use of soil information to determine application of ground penetrating radar. J. Appl. Geophys. 1995, 33, 101–108. 9. Tischler, M.A.; Collins, M.E.; Grunwald, S. Integration of ground-penetrating radar data, global positioning systems, and geographic information systems to create three-dimensional soil models. Proc. Ninth Int. Conf. on GPR; Santa Barbara, CA, 2002; 313–316. 10. Daniels, J.J.; Grumman, D.; Vendl, M. Coincident antenna three dimensional GPR. J. Environ. Eng. Geophys. 1997, 2 (1), 1–9. 11. Topp, G.C.; Davis, J.L.; Annan, A.P. Electromagnetic determination of soil water content: measurements in coaxial transmission lines. Water Resour. Res. 1980, 16 (3), 574–582.
Global Resources Paul Reich Hari Eswaran United States Department of Agriculture-Natural Resources Conservation Service (USDA-NRCS), Washington, D.C., U.S.A.
INTRODUCTION A biome is defined as ‘‘a community of organisms interacting with one another and with the chemical and physical factors making up their environments.’’[1] For most purposes, the term biome is used to identify the natural habitat conditions around the world. Depending on the purpose, the global ecosystem is divided into units each characterized by a specific combination of climatic factors. Two major determinants of biome type are precipitation (total and its distribution) and air temperature. These two elements of climate have been commonly used to define the major biomes of the world. A third variable that affects the habitat type is the soil. This section presents a general overview of the soils characterizing the major biomes of the world. Detailed maps showing the biomes of the world are not available due to conceptual differences of definitions and reliable global databases. There are many excellent and detailed studies of specific habitats around the world, and using these and the global soils and climate database of the world,[2] a map showing the distribution of the major biomes was drawn. The terms used to describe the biomes are common in use, but their subdivisions are based on important differentiating factors. MAJOR BIOMES The five major biomes of the world and their subdivisions are listed in Table 1 and their distribution is shown in Fig. 1 Some geographers have used elevation as a differentiating factor and recognized a ‘‘montane biome.’’ This biome’s small extent precludes its description in this section. Few geographers recognize the Mediterranean biome as presented here as a subdivision of the Temperate biome. Within each biome, some major distinction is made. In the Polar biome, an attempt is made to differentiate areas with permafrost and warmer areas with intermittent permafrost. The latter is termed ‘‘interfrost.’’ The Boreal Forest biome has a humid and a semiarid counterpart similar to the temperate and tropical Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042695 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
zones. The semiarid vegetation is generally grass or shrubs. The desert areas are divided into hot, cool, and cold equivalents. Deserts occupy about 30% of the global ice-free landmass. Potential evapotranspiration exceeds precipitation during most days of the year, and the biome shows the greatest contrast in temperature, both diurnal and seasonal. Desert vegetation is very sparse with a few isolated shrubs dominated by succulents and annuals. Grasses and forbs become more dominant at the margins. The tropics occupy about 27% of the landmass and are characterized by only a small variation in temperature during the year. The soil moisture conditions range from semiarid to humid. The availability of soil moisture determines the biota. The temperate grassland and forest biome occupies about 15%. The cold biomes, the boreal and polar, are mainly in the northern latitudes with small areas in South America. The low temperatures control the flora and fauna, and vegetation is scarce to nonexistent in the extreme cold polar regions. Each of these areas has specific kinds of soils that have developed as a response to the specific soil moisture and temperature conditions. The diversity in vegetation has its equivalent in fauna with animal species adapting to the specific bio-climatic conditions. Within each of the biomes, there are specific conditions that promote unique flora and fauna. Examples of such localized systems are volcanic hot springs, wetlands, and oases. Soils of the Major Biomes Soil temperature and moisture, with their seasonal and annual variations, are an integral part of the soil classification system called Soil Taxonomy[3] which is used here. As Fig. 1 and Table 1 are based on soil moisture and temperature conditions, there is an implied link between the biomes and their soil resource endowments. The purpose of this introductory section is to present the general geographic distribution of the biomes and the major soils characterizing each. The major soil orders are listed in Table 2. The subsequent sections elaborate on the soil resources of each of the six biomes listed in Table 1. 765
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Table 1 Major global biomes with subdivisions and their areas Global land area Biome
Subdivision
Remarks
In thousand km2 10,547 9,685
8.06 7.40
15.46
3,552 9,446
2.72 7.22
9.94
In%
In%
Polar
Permafrost Interfrost
Mosses and lichens Shrubs and stunted trees
Boreal
Semiarid Humid
Shrub Forest
Temperate
Semiarid Humid Mediterranean warm Mediterranean cold
Grassland Forest Shrubs and forest Forbs and shrubs
7,348 12,453 3,624 791
5.62 9.52 2.77 0.60
15.14
Desert
Hot Cool Cold
Barren Barren Barren
4,418 28,521 5,599
3.38 21.81 4.28
29.47
Tropical
Semiarid Humid
Grassland, savanna Forests
20,299 14,514
15.52 11.10
26.62
130,796
100.00
Total
Polar Biome Characterized largely by a mean annual soil temperature of less than 0 C, the Polar biome occupies a large land mass adjacent to the Arctic circle to about 60 N latitude. This is generally the ice-free land of the northern latitudes. The sub-zero soil temperatures that prevail during most of the year are conducive to the formation of
permafrost. The dominant soils of the region are Gelisols, occupying 59% of the Polar biome. Turbels freeze and thaw once or more during a year which triggers cryoturbation or physical mixing of the soil material. The Orthels are generally shallower or drier soils and have little or no cryoturbation. The low temperatures and periodic moisture saturation promote the accumulation of organic matter. The Histels are characterized by the
Fig. 1 Major biomes.
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Global Resources
Table 2 Dominant soils in the major biomes (Area in thousand km2) Polar
Boreal
Temperate
Desert
Tropics
Ice-free land
Permafrost
Interfrost
Semiarid
Humid
Semiarid
Humid
Mediterranean warm
Mediterranean cold
Warm
Cool
Cold
Semiarid
Humid
Gelisols
11,869
10,476
1,393
—
—
—
—
—
—
—
—
—
—
—
Histosols
1,526
—
—
299
686
17
8
—
Spodosols
4,596
55
1,058
227
2,566
105
450
39
6
—
975
6
56
47
196
26
135
32
—
Soil Order
Andisols Oxisols
9,811
—
—
Vertisols
3,160
—
—
2
—
60
76
—
1
14
Aridisols
15,629
Ultisols
11,053
Mollisols Alfisols
1 —
9,161 12,621
9
—
— 15
82
1
—
17
23 —
28
10 651
0
353
18
203
23
1,824
11,014
2,013
266
3,122
20
18
—
—
—
1,110
2,255
136
176
—
—
4,165
638
—
3,566
2,502
342
3,225
1,093
1,059
511
1,280
1,232
874
323
1,002
1,816
1,867
2,149
860
125
49 —
—
6,751
167
3,333
1,636
3,078
683
89
—
—
—
280
172
232
1,173
1,697
807
45
1,708
10,693
— 9,685
87
4
239
147
—
6,199
1,170
27
0
—
10,547
3,387
—
99
21,805 7,122
235
184
21,467 130,796
61
198
303
—
—
—
281
9
Entisols Total
14
37
595
Inceptisols Miscellaneous
93
516
1
20
4
6
153
553
5,016
853
3,552
9,446
7,348
12,453
3,624
791
4,418
28,521
5,599
44
1
4,371
3,240
—
—
20,299
14,514
767
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high organic matter and occupy about 5% of the Polar biome. These organic soils form the largest contiguous extent of such soils in the world and serve as an important sink of CO2. Other soils that occur in the Tundra zone are Inceptisols 33%, Spodosols 6%, while Mollisols and Entisols are each 1% of the area.[4] Boreal Forest Biome Bordering the southern flank of the Polar biome is the Boreal Forest biome in the northern hemisphere. The high volcanic area between Chile and Argentina has similar climatic regimes but the nature of the soil and physiography may result in a different set of habitat conditions. There are about 243,000 km2 of Andisols or volcanic ash soils characterizing the Boreal Forest biome in the southern hemisphere. Such soils only occur as a small area in the Kamchatca Peninsula in the Northern Hemisphere. In Northern Europe and Siberia, the Boreal Forest biome has a humid part and is bordered in its southern periphery by a semiarid to arid part. In Canada, the semiarid part is in the middle of the continent. A range of soils are present and the most extensive are the Spodosols, which occupy 2.7 million km2 (20.6%). The Spodosols are mostly in the humid part of the Boreal Forest biome and form under acid vegetation. Histosols are present in the depressions in this cold region. Temperate Grassland and Forest Biome The Temperate Grassland and Forest biome extends from about 25 to 55 N with counterparts in the Southern Hemisphere. Large areas in this belt are also deserts. Due to the favorable climate and soil endowments of this biome, much of the land is used for agriculture and native habitats are local and sporadic. About 50% of the zone (12.1 million km2) is occupied by Mollisols and Alfisols (grasslands), and Ultisols in the forests. Their general good fertility and tilth have made them in great demand for grain production. Due to the long history of civilization in the Temperate Grassland and Forest biome of Europe and China, pristine ecosystems are rare. In large areas, there have been successive replacements and changes in the floral and faunal composition. Within the Temperate biome, are areas characterized by moist winters and dry summers. These Mediterranean conditions are conducive to unique ecosystems. These areas occur around the Mediterranean Sea and small areas in the western U.S. and southern Australia. Desert Biome Deserts occupy about 38.6 million km2 and may be distinguished as warm (or tropical), cool (or temperate)
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Global Resources
and cold (or boreal) kinds of habitats. Though the biome is characterized by lack of moisture for normal vegetative growth of most plants, the ambient temperature conditions further distinguish the habitat conditions. About 38.6% of the Desert biome is occupied by Aridisols, which by definition have some kind of subsurface horizon. Shifting sands or moving dunes occupy about 13.7% and Entisols, which are very recent deposits, occupying about 33% of the Desert biome. The harshness of the environment has resulted in plants and animals with special adaptive features. Many of the Aridisols are increasingly used for agriculture when irrigation facilities are made available. In this fragile ecosystem, both soil and habitat conditions are drastically altered when irrigation is introduced. Tropics Biome An absence of winter and summer temperature extremes characterizes the Tropics biome, which occupy about 34.8 million km2. Availability of moisture separates the semiarid from the humid tropics. As a corollary to the desert, in the humid tropics there are the perhumid areas where the potential evapotranspiration never exceeds the precipitation during any month of the year. This is a biomic condition that deserves much greater detailed studies. The Tropics biome is the home to the Oxisols (9.6 million km2), which are unique to this biome. These are highly weathered soils where the original vegetation is closed or open forests. Most of the plant nutrients are concentrated in the top 5 cm of the soil and recycled through plant uptake and leaf fall. Ultisols also occur in this biome. Apart from these soils, there are small areas of most of the other soil orders. The wetlands of the tropics present a separate and unique habitat condition and those along the coast have some special soils.
REFERENCES 1. Tootil, E., Ed.; Dictionary of Biology; Intercontinental Kook Productions, Ltd.: Maidenhead, Berkshire, England, 1980. 2. Eswaran, H.; Beinroth, F.H.; Kimble, J.; Cook, T. Soil diversity in the tropics: implications for agricultural development. In Myths and Science of Soils of the Tropics; Lal, R., Sanchez, P.A., Eds.; Soil Sci. Soc. Am. Spec. Publ. 1992; 29, 1–16. 3. Soil survey staff. In Soil Taxonomy: A Basic System of Soil Classification for Making and Interpreting Soil Surveys, 2nd Ed.; Natural Resources Conservation Service. US Department of Agriculture, Handbook 436; US Government Printing Office: Washington, DC, 1999. 4. Keys to Soil Taxonomy, 9th Ed.; US Government Printing Office, 2003.
Global Warming: Carbon Sequestration to Mitigate Keith E. Idso Center for the Study of Carbon Dioxide and Global Change, Tempe, Arizona, U.S.A.
Sherwood E. Idso United States Water Conservation Laboratory, Phoenix, Arizona, U.S.A.
INTRODUCTION Concomitant with mankind’s growing numbers and the progression of the Industrial Revolution, there has been a significant increase in the burning of fossil fuels (coal, gas, and oil) over the past 200 yr, the carbon dioxide emissions from which have led to ever-increasing concentrations of atmospheric CO2. This ‘‘large-scale geophysical experiment,’’ to borrow the words of two of the phenomenon’s early investigators,[1] is still ongoing and expected to continue throughout the current century. Furthermore, this enriching of the air with CO2 is looked upon with great concern, because CO2 is an important greenhouse gas, the augmentation of which is believed by many to have the potential to produce significant global warming. Therefore, and because of perceived serious consequences, such as the melting of polar ice, rising sea levels, coastal flooding, and more frequent and intense droughts, floods, and storms,[2] a concerted effort is underway to slow the rate at which CO2 accumulates in the atmosphere, with the goal of stabilizing its concentration at a level that would prevent dangerous anthropogenic interference with the planet’s climate system. One of the more promising ways of reducing the rate of rise of the air’s CO2 content is to encourage land management policies that promote plant growth, which removes CO2 from the atmosphere and sequesters its carbon, first in vegetative tissues and ultimately in soils. Some of these policies deal with managed forests and agro-ecosystems, while others apply to natural ecosystems, such as unmanaged forests and grasslands. In all instances, however, questions abound. Can carbon inputs to soils really be enhanced or carbon losses reduced? Can carbon storage in recalcitrant fractions of soil organic matter be increased, making it possible to successfully maintain new stores of sequestered carbon for long periods? And what if global warming runs wild? Will the ensuing rise in temperature stimulate plant and microbial respiration rates, returning even more CO2 to the air than is removed by photosynthesis and leading to a negative net ecosystem exchange of carbon? These important questions rank Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001665 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
high on the priority lists of many research organizations concerned about the planet’s future climate and the sustainability of the biosphere.
REMOVING CARBON FROM THE AIR The Role of Man There are only two ways to significantly increase the natural flux of carbon from the atmosphere to the biosphere within the time frame required for effective ameliorative action if the ongoing rise in the air’s CO2 content is indeed a bona fide global warming threat: 1) increase the rate of vegetative CO2 assimilation (photosynthesis) per unit leaf area and=or 2) increase the total plant population of the globe, i.e., leaf area per unit land area. Additionally, these things must be done without increasing the rate at which carbon is lost from the soil. Man can do certain things to promote both of these phenomena while meeting the latter requirement as well. He can, for example, increase the rate of CO2 assimilation per unit leaf area in agro-ecosystems by supplying additional nutrients and water to his crops. As has recently been noted, however, there are significant carbon costs associated with the production and application of fertilizers, as well as the transport of irrigation water; and factoring the CO2 emissions of these activities into the equation often results in little net CO2 removal from the atmosphere via these intensified agricultural interventions.[3] Man can also draw more CO2 out of the air by increasing the acreage of land devoted to growing crops, but this approach simultaneously releases great stores of soil carbon built up over prior centuries. When the plow exposes buried organic matter and it is oxidized, for example, prodigious amounts of CO2 are produced and released to the atmosphere. But if a transition to less intensive tillage is made on fields that have a long history of conventional management and have thus been largely depleted of carbon, there is a good opportunity for nature to rebuild previously lost stores of soil organic matter.[4] 769
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This approach to carbon sequestration is doubly beneficial for it results in a net removal of CO2 from the atmosphere at the same time that it enhances a whole host of beneficial soil properties.[4,5] Also, abandoned farmlands will gradually replenish their carbon stores, both above- and below-ground, as native vegetation gradually reestablishes itself upon them. And, of course, the process can be hastened and made even more effective if trees are planted on such lands. Even without trees, it has been estimated that agricultural ‘‘best management practices’’ that employ conservation tillage techniques have the potential to boost the current U.S. farm and rangeland soil carbon sequestration rate of 20 million metric tons of carbon per year to fully 200 million metric tons per year,[6] which is approximately 13% of the country’s yearly carbon emissions.[7] Commercial forests also offer excellent opportunities for CO2 removal from the air for considerable periods of time, especially when harvested wood is used to produce products that have long lifetimes. In addition, since some species of trees, such as many of those found in tropical rainforests,[8] can live in excess of a thousand years, CO2 can be removed from the atmosphere and sequestered within their tissues—if man protects the trees from logging—until either long after the Age of Fossil Fuels has run its course or until significant changes in energy systems have reduced our dependence on fossil fuels and the CO2 content of the air has returned to a level no longer considered problematic. Furthermore, carbon transferred to the soil beneath the trees via root exudation and turnover has the potential to remain sequestered even longer.
The Role of Nature The fact that the biosphere has maintained itself over the eons in the face of a vast array of environmental perturbations (albeit with significant modifications) suggests that earth’s plant life has great resiliency and may even be able to exert a restraining influence on climate change. A particularly important negative feedback of this type is the biosphere’s ability to intensify its rate of carbon sequestration in the face of rising atmospheric CO2 concentrations, as this phenomenon slows the rate of rise of the air’s CO2 content and thereby reduces the degree of intensification of the atmosphere’s greenhouse effect. This particular climate-moderating influence of atmospheric CO2 enrichment was first described in quantitative terms by Idso.[9,10] It begins when the aerial fertilization effect produced by the rising CO2 content of the atmosphere elicits an increase in plant CO2 assimilation rate per unit leaf area and when the concomitant plant water use efficiency-enhancing
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Global Warming: Carbon Sequestration to Mitigate
effect of the elevated CO2 leads to an increase in the total plant population of the globe, due to the ability of more water-use-efficient plants to live and successfully reproduce in areas where it was formerly too dry for them to survive. In fact, these two effects are so powerful, they may actually be able to stabilize the CO2 content of the atmosphere sometime during the current century, but only if anthropogenic CO2 emission rates do not rise by an inordinate amount in the interim.[9,10] At the very least, together with the things man can do, they have the potential to ‘‘buy time’’ until other less-CO2-emitting technologies become available.[11]
KEEPING CARBON IN THE SOIL As more carbon is added to soils via CO2-enhanced root growth, turnover and exudation, as well as from CO2-induced increases in leaf litter and other decaying plant parts, the trick of significantly augmenting soil carbon sequestration is to keep at least the same percentage of this carbon in the soil as has historically been the case and to do so in the face of potential global warming. A number of studies have addressed various aspects of this subject in recent years, with most of them finding that atmospheric CO2 enrichment has little to no significant effect on plant litter decomposition rates. Furthermore, in nearly all of the cases where elevated CO2 was observed to impact this phenomenon, the extra CO2 was found to actually slow the rate of plant decomposition.[12] Much the same results have been obtained when analogous studies have used temperature as the independent variable. Warming has had either no effect on CO2 evolution from the soil, or it has led to an actual decrease in CO2 loss to the atmosphere.[13] Hence, the balance of evidence obtained from these studies suggests that the same—or a greater—percentage of plant material produced in a world of elevated atmospheric CO2 concentration (and possibly higher mean air temperature) would indeed be retained in the soils of the terrestrial biosphere. Even more compelling are the results of experiments where scientists have made direct measurements of changes in soil carbon storage under conditions of elevated atmospheric CO2. Nearly every such study has observed increases in soil organic matter. In a FreeAir CO2 Enrichment (FACE) experiment where portions of a cotton field were exposed to a 50% increase in atmospheric CO2, for example, Leavitt et al.[14] found that 10% of the organic carbon present in the soil below the CO2-enriched plants at the conclusion of the three-year experiment came from the extra CO2 supplied to the FACE plants. In addition, some
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Table 1 Potential rates of carbon sequestration (kilograms carbon per hectare per year) due to land management practices that could be employed for this purpose Improved rangeland management
50 to 150
Improved pastureland management Commercial fertilizer applications Manure applications Use of improved plant species
100 to 200 200 to 500 100 to 300
Improved grazing management
300 to 1300
Nitrogen fertilization of mountain meadows
100 to 200
Restoration of eroded soils
50 to 200
Restoration of mined lands
1000 to 3000
Conversion of cropland to pasture
400 to 1200
Conversion of cropland to natural vegetation
600 to 900
Conversion from conventional to conservation tillage No till Mulch till Ridge till
500 500 500
(Adapted from data reported by Follett, R.F.; Kimble, J.M.; Lal, R. The Potential of U.S. Grazing Lands to Sequester Carbon and Mitigate the Greenhouse Effect; Lewis Publishers, Boca Raton, FL, 2001; 1– 442, and by Ref.[4].)
of the stored carbon had made its way into a very recalcitrant portion of the soil organic matter that had an average soil residence time of 2200 yr. Here, too, most experiments indicate that concomitant increases in temperature do not negate the increased carbon storage produced by atmospheric CO2 enrichment. In a two-year study of perennial ryegrass grown at ambient and twice-ambient atmospheric CO2 concentrations, as well as ambient and ambient þ3 C temperature levels, for example, Casella and Soussana[15] determined that the elevated CO2 increased soil carbon storage by 32% and 96% at low and high levels of soil nitrogen supply, respectively, ‘‘with no significant increased temperature effect.’’ Hence, as in the case of studies of plant decomposition rates, the balance of evidence obtained from these studies also suggests that the same—or a greater— percentage of plant material produced in a world of elevated atmospheric CO2 concentration (and possibly higher mean air temperature) would indeed be retained in the soils of the terrestrial biosphere.
CONCLUSIONS As the air’s CO2 content continues to rise, there will almost certainly be a significant upward trend in the
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yearly production of terrestrial vegetative biomass, due to the growth-enhancing aerial fertilization effect of atmospheric CO2 enrichment and the concomitant CO2-induced increase in plant water use efficiency that enables plants to grow where it is currently too dry for them. Experimental evidence further suggests that at least the same percentage—but in all likelihood more—of this yearly-increasing mass of plant tissue will be sequestered in earth’s soils. Consequently, it is almost impossible to conclude that the carbon sequestering prowess of the planet will not be greatly enhanced in the years ahead, even without any overt actions on the part of man. Hence, if the nations of the earth were to implement even a modicum of carbon-conserving measures—such as 1)using minimum tillage techniques wherever possible in agricultural settings; 2) allowing abandoned agricultural land to revert to its natural vegetative state; 3)allowing stands of trees that can grow to very old age to actually do so; and 4) employing wise forestry practices to produce wood for making products that have long lifetimes— it is possible that the antiwarming feedback produced by the subsequent removal of CO2 from the atmosphere would be sufficient to keep the risk of potential greenhouse gas-induced global warming at an acceptable level. Estimates of the carbon-sequestering power of some of these ‘‘best management practices’’ are given in Table 1.
REFERENCES 1. Revelle, R.; Suess, H.E. Carbon dioxide exchange between atmosphere and ocean and the question of an increase of atmospheric CO2 during the past decades. Tellus 1957, 9, 18–27. 2. Intergovernmental panel on climate change. In Climate Change 2001: The Scientific Basis, Summary for Policy Makers and Technical Summary of the Working Group I Report; Cambridge University Press: Cambridge, UK, 2001; 1–98. 3. Schlesinger, W.H. Carbon sequestration in soils: some cautions amidst optimism. Agric. Ecosys. Environ. 2000, 82, 121–127. 4. Lal, R.; Kimble, J.M.; Follett, R.F.; Cole, C.V. The Potential for U.S. Cropland to Sequester Carbon and Mitigate the Greenhouse Effect; Sleeping Bear Press: Chelsea, MI, 1998; 1–128. 5. Idso, S.B. Carbon Dioxide and Global Change: Earth in Transition; IBR Press: Tempe, AZ, 1989; 1–292. 6. Jawson, M.D.; Shafer, S.R. Carbon credits on the Chicago board of trade? Agric. Res. 2001, 49 (2), 2. 7. Comis, D.; Becker, H.; Stelljes, K.B. Depositing carbon in the bank. Agric. Res. 2001, 49 (2), 4–7. 8. Chambers, J.Q.; Higuchi, N.; Schimel, J.P. Ancient trees in Amazonia. Nature 1998, 391, 135–136. 9. Idso, S.B. The aerial fertilization effect of CO2 and its implications for global carbon cycling and maximum
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greenhouse warming. Bull. Amer. Meteorol. Soc. 1991, 72, 962–965. 10. Idso, S.B. Reply to comments of L.D. Danny Harvey, Bert Bolin, and P. Lehmann. Bull. Amer. Meteorol. Soc. 1991, 72, 1910–1914.. 11. Izaurralde, R.C.; Rosenberg, N.J.; Lal, R. Mitigation of climatic change by soil carbon sequestration: issues of science, monitoring, and degraded lands. Adv. Agron. 2001, 70, 1–75. 12. Nitschelm, J.J.; Luscher, A.; Hartwig, U.A.; van Kessel, C. Using stable isotopes to determine soil carbon input differences under ambient and elevated atmospheric CO2 conditions. Global Change Biol. 1997, 3, 411–416.
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Global Warming: Carbon Sequestration to Mitigate
13. van Ginkel, J.H.; Whitmore, A.P.; Gorissen, A. Lolium perenne grasslands may function as a sink for atmospheric carbon dioxide. J. Environ. Quality 1999, 28, 1580–1584. 14. Leavitt, S.W.; Paul, E.A.; Kimball, B.A.; Hendrey, G.R.; Mauney, J.R.; Rauschkolb, R.; Rogers, H.; Lewin, K.F.; Nagy, J.; Pinter, P.J., Jr.; Johnson, H.B., Jr. Carbon isotope dynamics of free-air CO2-enriched cotton and soils. Agric. For. Meteorol. 1994, 70, 87–101. 15. Casella, E.; Soussana, J.-F. Long-term effects of CO2 enrichment and temperature increase on the carbon balance of a temperate grass sward. J. Exp. Bot. 1997, 48, 1309–1321.
Grass Strip Hydrology Hossein Ghadiri Calvin W. Rose Faculty of Environmental Sciences, Griffith University, Nathan Campus, Nathan, Queensland, Australia
INTRODUCTION The use of vegetated strips is one of the simplest and most widely employed methods of reducing the flux of eroding soil and associated chemicals across slopes (Fig. 1) and into streams. Grass strips of various type, width, spacing, density, rigidity, and strength have been used for soil erosion control on sloping lands and for water quality control in riparian zones with varying degrees of success.[1–3] It was widely believed, with some support from field studies, that the effectiveness of buffer strips in sediment trapping was largely because of a filter-type action, with strips filtering out the suspended sediment as runoff passes through them, leaving the emerging runoff significantly cleaner in terms of sediment, nutrients, and soil-sorbed contaminants. Because of such perceived mode of operation, buffer strips have been commonly referred to as ‘‘filter strips.’’[4,5] However, most recent studies have shown that a filtering action is not a major contributing process to buffer strip effectiveness. Considerable experimental evidence in the literature suggests little or no net deposition within the buffer strips.[6–9] Some have reported the occurrence of erosion, rather than deposition, inside the grass strips.[4,8] Recent studies have sought to understand the mechanics of flow through grass strips, seeking the real reason for the inconsistencies observed in their effectiveness.[2,7–11] It has been recognized that a flowresistive element such as a cross-slope strip of vegetation modifies the hydrology of overland flow, and that this modification has implications for the transport and deposition of sediment and associated nutrients in and around the strips.[7,8,11,12] It is the hydraulic consequence for overland flow when it meets and flows through a resistive element, which first needs to be understood to ascertain the effectiveness, or otherwise, of grass strips in reducing erosion, enhancing deposition, and reducing the transportation of pollutants into surface water bodies. Such understanding is also necessary for the development of models and the prediction of buffer strip effectiveness under different conditions. This article covers the most recent progresses made in this area. Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120014316 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
EFFECT OF BUFFER STRIPS ON FLOW HYDRAULICS One of the main hydrologic features of flow through grass strips is the formation of a pronounced backwater,[8] or a zone of hydraulic adjustment.[9,13] The length of this zone appears to be dependent on land slope, strip density, and flow rate (Fig. 2). At any constant flow rate, the length of backwater B has been shown to be linearly related to the ratio of strip density over slope:
B ¼ k
D S
ð1Þ
where k is a proportionality constant, D is percent grass coverage in the strip, and S is slope. Eq. (1) shows that decreasing density and increasing slope both have the effect of decreasing backwater length[8] (Fig. 3). The starting point of the backwater region is a hydraulic jump, which moves closer to the strip as the slope increases or as the grass density decreases. The front edge of the backwater is usually sharp and clear at high slopes (Figs. 2 and 3), getting less distinct as it moves away from the strips with decreasing slope or increasing grass density. At low slopes of around 1%, the front edge of the backwater breaks into a number of waves. The width of the strips does not appear to play an important role in backwater formation or its characteristics.[8] Theoretical interpretations of flow through grass strips are very few. However, there is a long history of investigation of hydraulic jumps in the hydraulic literature. Chow[13] developed the hydraulic jump theory for deep rectangular channel flow encountering solid barriers such as dams and wears. This interpretation does not apply to our condition of shallow unconfined flow being partially blocked by porous barriers such as grass or nail strips. Rose et al.[9] have shown that the change in hydraulics because of the presence of a buffer strip can be understood in terms of the conservation of momentum theory. 773
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Grass Strip Hydrology
Fig. 1 Strips of Vetiver grass used as a soil erosion control technique in Queensland, Australia. (Courtesy of Mr. Cyril Ciesiolka of DPI, Toowoomba, Queensland, Australia.) (View this art in color at www.dekker. com.)
EFFECT OF BUFFER STRIPS ON SEDIMENT TRANSPORT Runoff sediment concentration results from the balance of two quite rapid processes: entrainment (or re-entrainment) by the overland flow, and deposition. Even a modest reduction in flow velocity in the backwater region produced by the vegetation buffer strips reduces the entrainment rate, resulting in net deposition in this region. Thus the effect of grass strips on erosion=sedimentation is mainly through their impact on surface hydrology.
Net deposition of coarse sediment load commences at the starting edge of the backwater (or at the hydraulic jump) (Fig. 2). This site of initial net deposition approaches the strip with an increase in slope, or a decrease in strip density, eventually burying and entering the strip. Sediment deposition generally follows the hydrologic pattern established at the early stages of the flow, as predicted by Eq. (1). Little, if any, deposition appears to take place inside the strips prior to the point of grass collapse.[6,8,14] Sediment that deposits in the backwater moves into the strip zone only after burying the first few rows of the vegetation.[2] The unburied rows then become the new front edge of the strip. However, once the first rows of the strips give way, the process usually continues until the entire width of the strip collapses at one point or more (Fig. 4). Many researchers have reported that the width of the grass strip has little effect on the efficiency of the strips in slowing down the flow, or unloading its sediment content.[2,15] However, there are others who have reported the opposite.[1,3] The disagreement between the two groups is yet to be resolved. THEORETICAL INTERPRETATION OF SEDIMENT TRANSPORT THROUGH BUFFER STRIPS
Fig. 2 Illustrating flow and sediment deposition in the backwater region of a barrier strip.
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Mass conservation of deposited sediment was used by several researchers[16,17] to describe the resulting change in the shape of the deposited layer. However, their models do not represent the hydrology and net deposition upslope of the grass strips (Fig. 2), and only deal with single-size particles. A more appropriate theoretical
Grass Strip Hydrology
775
Fig. 3 Effect of slope on the length of backwater (flow height recorded digitally; flow is from left to right and the two long vertical lines on each trace show the beginning and the end of the grass strip).
explanation of flow through porous barriers is given by Rose et al.,[12] who showed that the appropriate equation to solve (under steady flow conditions) is as follows:
class i, x is downslope distance, di the rate of deposition per unit area, and rri is the rate of re-entrainment of newly deposited sediment of size class i.
d dci ¼ di rri Mdi ¼ q dx dt
EFFECT OF BUFFER STRIPS ON CHEMICAL TRANSPORT
where t is time, Mdi is the mass per unit area of sediment of size class i in the region of net deposition, q is volumetric water flux, ci is sediment concentration of size
Soil chemicals are preferentially sorbed to the finer fractions of soil.[18,19] Buffer strip influences the transport of sorbed chemicals mainly through sediment sorting
Fig. 4 Collapsed grass strip on 8% slope (flow from left to right; total collapse happened after the first few rows of grass were buried under the deposited sediment; vertical white bar is a 15-cm ruler). (View this art in color at www.dekker.com.)
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processes, which take place in the backwater. Sediment passing though the strips is significantly finer than that initially dislodged by the flow. It was shown by Ghadiri and Rose[19] that the concentrations of organic matter, sorbed nutrients, and agricultural chemicals can be significantly higher on the finer particles. The preferential deposition of larger aggregates and particles in the backwater leaves the sediment, which emerges from the buffer strip, relatively enriched in fine particles and thus in soil-sorbed chemicals. Such transmitted fine particles, together with their chemical load, may stay in suspension until entry into receiving waters. Therefore, grass strips are less effective in reducing overland transport of solutes or solids-associated chemical pollutants than they are in reducing sediment load.
CONCLUSIONS Buffer strips behave like porous barriers against flow, creating backwater regions upslope of the strips with reduced flow velocity and increased depth in a length that varies with slope, strip density, and flow rate. For a constant flow rate, there is a linear relationship between backwater length and the ratio of strip density over slope. Momentum theory appears to provide a reasonably good prediction, both of the shape of the water profile within the strips, and of the slope and extent of backwater region. The zone of hydraulic adjustment or backwater is a zone of considerable deposition from sediment-laden flow. The efficiency of the grass strips in slowing down the flow and unloading its sediment in the backwater region appears to be largely independent of the width of strips in the flow direction. The layer of deposited sediment formed in the backwater region tends to be richer in larger particles than the eroding sediment. Sediment size distribution appears to be a dominant factor governing the efficiency of the buffer strip in trapping sediment. Soil-sorbed nutrients and other agricultural chemicals are mainly attached to finer soil particles, which are more likely to pass through the strips largely unchanged. Thus the sediment that emerges from a buffer strip can be enriched in such chemicals relative to the eroding soil. Hence although buffer strips can be very efficient in forcing the deposition of suspended sediment in the backwater region on certain slopes, they are helpful, but less effective, in preventing chemical pollutants from entering surface water bodies.
REFERENCES 1. Dickey, E.C.; Vanderholm, D.H. Vegetation filter treatment of livestock feedlot runoff. J. Environ. Qual. 1981, 10, 279–284.
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Grass Strip Hydrology
2. Dillaha, T.A.; Reneau, R.B.; Mostaghimi, S.; Lee, D. Vegetation filter strips for agricultural nonpoint source pollution control. Trans. ASAE 1989, 32, 513–519. 3. Van Dijk, P.M.; Kwaad, F.J.P.; Klapwijk, M. Retention of water and sediment by grass strips. Hydrol. Process. 1996, 10, 1069–1080. 4. Loch, L.J.; Espigares, T.; Costantini, A.; Garthe, R.; Bubb, K. Vegetative filter strips to control sediment movement in forest plantations: validation of a simple model using field data. Aust. J. Soil Res. 1999, 37, 929–946. 5. Jin, C.X.; Romkens, M.J.M. Experimental studies of factors in determining sediment trapping in vegetative filter strips. Trans. ASAE 2001, 44, 277–288. 6. Lidgi, E.; Morgan, R.P.C. Contour grass strips: a laboratory simulation of their role in soil erosion control. Soil Technol. 1995, 8, 109–117. 7. Ghadiri, H.; Hogarth, W.; Rose, C.W. The Effectiveness of Grass Strips for the Control of Sediment and Associated Pollutant Transport of Runoff; Stone, M., Ed.; International Association of Hydrologic Sciences (IAHS) Publication No. 263, 2000; 83–91. 8. Ghadiri, H.; Rose, C.W.; Hogarth, W.L. The influence of grass and porous barrier strips on runoff hydrology and sediment transport. Trans. ASAE 2001, 44, 259–268. 9. Rose, C.W.; Hogarth, W.; Ghadiri, H.; Parlange, J.-Y.; Okom, A. Overland flow to and through a segment of uniform resistance. J. Hydrol. 2002, 255, 134–150. 10. Hairsine, P.B. In Comparing Grass Filter Strips and Near-Natural Riparian Forests for Buffering Intense Hillslope, Sediment Sources, Proceedings of the 1st National Conference on Stream Management in Australia; CRC for Catchment Hydrology, Monash University: Melbourne, Australia, 1996. 11. Dabney, S.M.; Meyer, L.D.; Harmon, W.C.; Alonso, C.V.; Foster, G.R. Depositional patterns of sediment trapped by grass hedges. Trans. ASAE 1995, 38, 1719–1729. 12. Rose, C.W.; Yu, B.; Hogarth, W.; Okom, E.A.; Ghadiri, H. Theoretical interpretation of the spatial and size distribution of sediment deposited by buffer strips from flow at modest land slopes. J. Hydrol. 2003, in press. 13. Chow, V.T. Open Channel Hydraulics; McGraw-Hill Book Company: Singapore, 1959. 14. Boubakari, M.; Morgan, R.P.C. Contour grass strips for soil erosion control on steep lands: a laboratory evaluation. Soil Use Manage. 1999, 15, 21–26. 15. Smith, C.M. Riparian afforestation effects on water yields and water quality in pasture catchments. J. Environ. Qual. 1992, 21, 237–245. 16. Munoz-Carpena, R.; Pearson, J.E.; Gilliam, J.W. Modelling hydrology and sediment transport in vegetative filter strips. J. Hydrol. 1999, 214, 111–129. 17. Deletic, A. Modelling of water and sediment transport over grasses areas. J. Hydrol. 2001, 248, 168–182. 18. Ghadiri, H.; Rose, C.W. Sorbed chemical transport in overland flow: Part 1. An enrichment mechanism for sorbed nutrients and pesticides. J. Environ. Qual. 1991, 20, 628–633. 19. Ghadiri, H.; Rose, C.W. Sorbed chemical transport in overland flow: Part 2. Enrichment ratio of sorbed chemicals and its variation with time, particle size and erosion process. J. Environ. Qual. 1991, 20, 634–641.
Grasslands Soils Douglas D. Malo South Dakota State University, Brookings, South Dakota, U.S.A.
INTRODUCTION Soil science developed in recent times in response to problems. In Europe during the 1800s, food shortages, social upheavals, and declining soil productivity brought about the need to study soil to improve and increase its productivity. At the same time, in Russia, a need arose to administer and manage geographically diverse soil resources. Russia had large areas of fertile, productive soils unlike those in Europe. As a result, Russian scientists developed an inventory of agricultural resources and determined the factors causing soils to vary across Russia. Soils were found to have relationships with climatic and vegetative zones.[1] It is from these concepts that the living soil individual was developed. Soil is a natural body and not a geologic formation. With time, soil develops from the parent material under the influence of the climate, vegetation, and topography (relief ). These five factors of soil formation are interdependent and not independent. Changing one soil-forming factor often changes other soil-forming factors. Changing any one, some, or all of the soil-forming factors causes differences in soils and soil profiles.[2] Soils and plants interact and evolve together forming different ecosystems. These soil–plant relationships are often most strongly expressed when native vegetation is present. The soils in grasslands, a major ecosystem, are very different from other soils due to this interaction.
the steppe regions of Europe, Russia, Mongolia, and Northern China) are dominated by grassland soils (Fig. 1). The largest grassland area in the world is found in Kazakhstan, Russia, and the Ukraine. Generally, small grains and grain sorghum are raised in the drier grassland regions. The warmer, humid grasslands are better suited for row crops like maize (corn) and soybeans. Where slopes are too great for cultivation or the climate is not favorable, grassland soils are used for pasture and rangeland. Native grassland types include: desert grasslands, 70%, Hart[11] and Keller and Bliesner[8] presented " CU ¼ 100 1
# s 2 0:5 x
p
ð8Þ
where s is the standard deviation of the catch depth (mm) or volume (ml). Eq. (8) approximates the normal distribution for the catch amounts. The CU should be weighted by the area represented by the container[12] when the sprinkler catch containers intentionally represent unequal land areas, as is the case for catch containers beneath a center pivot. Heermann and Hein[12] revised the CU formula (Eq. 8) to reflect the weighted area, particularly intended for a center pivot sprinkler, as follows:
CUðH&HÞ
P 39 8 2 P
> PVi Si
> > > Si Vi < Si 6 7= 7 P ¼ 100 1 6 4 5> > ðVi Si Þ > > ; : ð9Þ
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where Si is the distance (m) from the pivot to the ith equally spaced catch container and Vi is the volume of the catch in the ith container (mm or ml). Low-Quarter Distribution Uniformity The distribution uniformity represents the spatial evenness of the applied water across a field or a farm as well as within a field or farm. The general form of the distribution uniformity can be given as
DUp
Vp ¼ 100 Vf
ð10Þ
where DUp is the distribution uniformity (%) for the lowest p fraction of the field or farm (lowest one-half p ¼ 1=2, lowest one-quarter p ¼ 1=4), V p is the mean application volume (m3), and V p is the mean application volume (m3) for the whole field or farm. When p ¼ 1=2 and CU > 70%, then the DU and CU are essentially equal.[13] The USDA-NRCS (formerly, the Soil Conservation Service) has widely used DUlq (p ¼ 1=4) for surface irrigation to access the uniformity applied to a field, i.e., by the irrigation volume (amount) received by the lowest one-quarter of the field from applications for the whole field. Typically, DUp is based on the post-irrigation measurement[5] of water volume that infiltrates the soil because it can more easily be measured and better represents the water available to the crop. However, the postirrigation infiltrated water ignores any water intercepted by the crop and evaporated and any soil water evaporation that occurs before the measurement. Any water that percolates beneath the root zone or the sampling depth will also be ignored. The DU and CU coefficients are mathematically interrelated through the statistical variation (coefficient of variation, s/ x, Cv) and the type of distribution. Warrick[13] presented relationships between DU and CU for normal, log-normal, uniform, specialized power, beta-, and gamma-distributions of applied irrigations. Emission Uniformity For microirrigation systems, both the CU and DU concepts are impractical because the entire soil surface is not wetted. Keller and Karmeli[14] developed an equation for microirrigation design as follows h i q m EU ¼ 100 1 1:27ðCvm Þn1=2 q
ð11Þ
where EU is the design emission uniformity (%), Cvm is the manufacturer’s coefficient of variability in emission
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Irrigation Efficiency
device flow rate (1 hr1), n is the number of emitters per plant, qm is the minimum emission device flow rate is the (1 hr1) at the minimum system pressure, and q mean emission device flow rate (1 hr1). This equation is based on the DUlq concept,[4] and includes the influence of multiple emitters per plant that each may have a flow rate from a population of random flow rates based on the emission device manufacturing variation. Nakayama, Bucks, and Clemmens[15] developed a design coefficient based more closely on the CU concept for emission device flow rates from a normal distribution given as CUd ¼ 100ð1 0:798ðCvm Þn1=2 Þ
ð12Þ
where CUd is the coefficient of design uniformity (%) and the numerical value, 0.798, is 0:5 2 p from Eq. (8). Many additional factors affect microirrigation uniformity including hydraulic factors, topographic factors, and emitter plugging or clogging.
WATER USE EFFICIENCY The previous sections discussed the engineering aspects of irrigation efficiency. Irrigation efficiency is clearly influenced by the amount of water used in relation to the irrigation water applied to the crop and the uniformity of the applied water. These efficiency factors impact irrigation costs, irrigation design, and more important, in some cases, the crop productivity. The water use efficiency has been the most widely used parameter to describe irrigation effectiveness in terms of crop yield. Viets[16] defined water use efficiency as WUE ¼
Yg ET
ð13Þ
where WUE is water use efficiency (kg m3), Yg is the economic yield (g m2), and ET is the crop water use (mm). WUE is usually expressed by the economic yield, but it has been historically expressed as well in terms of the crop dry matter yield (either total biomass or aboveground dry matter). These two WUE bases (economic yield or dry matter yield) have led to some inconsistencies in the use of the WUE concept. The transpiration ratio (transpiration per unit dry matter) is a more consistent value that depends primarily on crop species and the environmental evaporative
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demand,[17] and it is simply the inverse of WUE expressed on a dry matter basis.
Irrigation Water Use Efficiency The previous discussion of WUE does not explicitly explain the crop yield response to irrigation. WUE is influenced by the crop water use (ET). Bos[3] defined a term for water use efficiency to characterize the influence of irrigation on WUE as WUE ¼
ðYgi Ygd Þ ðETi ETd Þ
ð14Þ
where WUE is irrigation water use efficiency (kg m3), Ygi is the economic yield (g m2) for irrigation level i, Ygd is the dryland yield (g m2; actually, the crop yield without irrigation), ETi is the evapotranspiration (mm) for irrigation level i, and ETd is the evapotranspiration of the dryland crops (or of the ET without irrigation). Although Eq. (14) seems easy to use, both Ygd and ETd are difficult to evaluate. If the purpose is to compare irrigation and dryland production systems, then dryland rather than nonirrigated conditions should be used. If the purpose is to compare irrigated regimes with an unirrigated regime, then appropriate values for Ygd and ETd should be used. Often, in most semiarid to arid locations, Ygd may be zero. Bos[3] defined irrigation water use efficiency as IWUE ¼
ðYgi Ygd Þ IRRi
ð15Þ
where IWUE is the irrigation efficiency (kg m3) and IRRi is the irrigation water applied (mm) for irrigation level i. In Eq. (15), Ygd may be often zero in many arid situations.
CONCLUSIONS Irrigation efficiency is an important engineering term that involves understanding soil and agronomic sciences to achieve the greatest benefit from irrigation. The enhanced understanding of irrigation efficiency can improve the beneficial use of limited and declining water resources needed to enhance crop and food production from irrigated lands.
REFERENCES 1. Israelsen, O.R.; Hansen, V.E. Irrigation Principles and Practices, 3rd Ed.; Wiley: New York, 1962; 447 pp.
Irrigation Efficiency
2. ASCE. Describing irrigation efficiency and uniformity. J. Irrig. Drain. Div., ASCE 1978, 104 (IR1), 35–41. 3. Bos, M.G. Standards for irrigation efficiencies of ICID. J. Irrig. Drain. Div., ASCE 1979, 105 (IR1), 37–43. 4. Heermann, D.F.; Wallender, W.W.; Bos, M.G. Irrigation efficiency and uniformity. In Management of Farm Irrigation Systems; Hoffman, G.J., Howell, T.A., Solomon, K.H., Eds.; Am. Soc. Agric. Engrs: St. Joseph, MI, 1990; 125–149. 5. Burt, C.M.; Clemmens, A.J.; Strelkoff, T.S.; Solomon, K.H.; Bliesner, R.D.; Hardy, L.A.; Howell, T.A.; Eisenhauer, D.E. Irrigation performance measures: efficiency and uniformity. J. Irrig. Drain. Eng. 1997, 123 (3), 423–442. 6. Howell, T.A. Irrigation efficiencies. In Handbook of Engineering in Agriculture; Brown, R.H., Ed.; CRC Press: Boca Raton, FL, 1988; Vol. I, 173–184. 7. Merriam, J.L.; Keller, J. Farm Irrigation System Evaluation: A Guide for Management; Utah State Univ.: Logan, UT, 1978; 271 pp. 8. Keller, J.; Bliesner, R.D. Sprinkle and Trickle Irrigation; The Blackburn Press: Caldwell, NJ, 2000; 652 pp. 9. U.S. salinity laboratory staff. In Diagnosis and Improvement of Saline and Alkali Soils; Handbook 60; U.S. Govt. Printing Office: Washington, DC, 1954; 160 pp.
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10. Christiansen, J.E. Irrigation by Sprinkling; California Agric. Exp. Bull. No. 570, Univ. of Calif.; Berkeley, CA, 1942; 94 pp. 11. Hart, W.E. Overhead irrigation by sprinkling. Agric. Eng. 1961, 42 (7), 354–355. 12. Heermann, D.F.; Hein, P.R. Performance characteristics of self-propelled center-pivot sprinkler machines. Trans. ASAE 1968, 11 (1), 11–15. 13. Warrick, A.W. Interrelationships of irrigation uniformity terms. J. Irrig. Drain. Eng., ASCE 1983, 109 (3), 317–332. 14. Keller, J.; Karmeli, D. Trickle Irrigation Design; Rainbird Sprinkler Manufacturing: Glendora, CA, 1975; 133 pp. 15. Nakayama, F.S.; Bucks, D.A.; Clemmens, A.J. Assessing trickle emitter application uniformity. Trans. ASAE 1979, 22 (4), 816–821. 16. Viets, F.G. Fertilizers and the efficient use of water. Adv. Agron. 1962, 14, 223–264. 17. Tanner, C.B.; Sinclair, T.R. Efficient use of water in crop production: research or re-search? In Limitations to Efficient Water Use in Crop Production; Taylor, H.M., Jordan, W.R., Sinclair, T.R., Eds.; Am. Soc. Agron., Crop Sci. Soc. Am., Soil Sci. Soc. Am.; Madison, WI, 1983; 1–27.
Irrigation Erosion Robert E. Sojka David L. Bjorneberg United States Department of Agriculture-Agricultural Research Service (USDA-ARS), Kimberly, Idaho, U.S.A.
INTRODUCTION Irrigation is important to global food production. About 15% of cropland[1] and 5% of food production land, which includes rangeland and permanent cropland,[2] are irrigated. However, irrigated land produces more than 30% of the world’s food,[3] which is 2.5 times as much per unit area compared with nonirrigated production.[1] In the United States, approximately 15% of the harvested cropland is irrigated, however, almost 40% of the total crop value is produced on irrigated land.[4] Although sprinkler- and drip-irrigated areas are increasing, most of the world’s irrigated land uses surface or flood irrigation. The countries with the largest irrigated areas are India—59,000,000 hectares (ha), China—52,580,000 ha, United States—21,400,000 ha, and Pakistan—18,000,000 ha.[2] These countries account for 55% of the world’s irrigated land; all other countries have less than 10 million ha each of irrigated land.[2] About 50% of the irrigated land in the United States is surface irrigated[5] although 95 to 99% of the irrigated land in India, China, and Pakistan is surface irrigated.[6] Soil erosion from irrigated fields has been discussed previously[7,8] and we focus on unique aspects of irrigation-induced soil erosion that are important when managing and simulating soil erosion on irrigated lands. Soil erosion mechanics can be divided into three components: detachment, transport, and deposition. Water droplets and flowing water detach soil particles; flowing water then transports these detached particles downstream; deposition occurs when flowing water can no longer transport the soil particles because flow rate decreases as water infiltrates or as rill slope or roughness change. Some particles are deposited within a few meters, although others are transported off the field with runoff water. These mechanisms are the same for surface irrigation, sprinkler irrigation, and rainfall; however, there are some systematic differences between irrigation and rainfall erosion, especially between surface irrigation and rainfall. SURFACE IRRIGATION Soil erosion is often a serious problem on surfaceirrigated land (Figs. 1 and 2). Erosion rates as high 942 Copyright © 2006 by Taylor & Francis
as 145 Mg=ha in 1 h[9] and 40 Mg=ha in 30 min[10] were reported in some early surface irrigation erosion studies. These extreme losses do not represent a sustained seasonal rate. Annual soil losses of 1 to 141 Mg=ha from surface irrigated fields were reported in a 1980 southern Idaho study.[11] Within-field erosion rates on the upper quarter of a furrow-irrigated field can be 10 to 30 times more than the field average erosion rate.[12] Some soil eroded from the upper end of a field is deposited on the lower end, whereas some soil leaves the field with runoff. Losing topsoil from the upper end of the field can decrease crop yields 25% compared with the lower end of the field.[13] Sediment cannot be transported without runoff. Runoff is planned with many surface irrigation schemes in order to irrigate all areas of the field adequately. Under ideal conditions, properly designed and managed sprinkler irrigation systems will not have any runoff from the irrigated area. However, economic and water supply constraints, along with variable slope and soil conditions, often force compromises in sprinkler irrigation design.
SPRINKLER IRRIGATION Runoff is rarely a problem with solid-set sprinkler irrigation systems because stationary sprinklers uniformly apply water at low rates (e.g., 2 mm=h). At the other end of the spectrum are systems with continuously moving laterals (center-pivot and lateral-move systems), which apply water to smaller areas (5–20 m wide) at higher rates than solid-set systems (e.g., 80 mm=h). Traveling lateral systems must irrigate large fields to reduce cost per unit area; this necessitates high instantaneous application rates to meet crop water requirements over the entire field. Application rates for center-pivot and lateral-move irrigation systems often exceed the soil infiltration rate, therefore runoff is almost always a potential problem. Sprinkler type, nozzle pressure, and nozzle size influence runoff and soil erosion by affecting application rate, wetted area, and droplet size. Low pressure sprinklers, which reduce energy costs, have smaller pattern widths and therefore greater application rates. Lower pressure also Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001575 Copyright # 2006 by Taylor & Francis. All rights reserved.
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SURFACE IRRIGATION AND RAINFALL EROSION DIFFERENCES
Fig. 1 White area in the field caused by erosion from more than 80 years of surface irrigation.
produces larger drops with greater impact energy on the soil. Sprinkler systems, particularly center pivots, operate on variable slopes and topography. Slope direction relative to the lateral affects how runoff accumulates. If the lateral is perpendicular to the slope direction, runoff will tend to move away from the lateral where water is being applied, allowing water to infiltrate before traveling very far. However, if the slope is parallel to the lateral, runoff can accumulate down slope and begin flowing in erosive streams. Furthermore, if the lateral is traveling up slope, runoff will flow onto a previously wetted area; whereas with down slope travel, runoff can flow onto dry soil. These factors are further complicated by wheel tracks from moving sprinkler systems that create compacted channels for water flow.
Fig. 2 Eroded irrigation furrows near the inflow end of a field.
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The most obvious difference between soil erosion from rain or sprinkler irrigation and from surface irrigation is the lack of water droplets impacting the soil during surface irrigation. This fundamental difference is important because droplet kinetic energy affects both erosion and infiltration.[14] When rain begins, droplets wet the soil surface and detach soil particles; as runoff begins, rills form in wet soil. Water flowing in rills is also exposed to falling raindrops, which affects detachment, transport, and deposition in the rills. For furrow irrigation, rills are mechanically formed in dry soil before irrigation begins. Water is applied to only a small portion of the soil surface. As water advances down the field, it flows over dry, loose soil on the first irrigation and dry, consolidated soil on subsequent irrigations. Irrigation water instantaneously wets the soil, rapidly displacing air adsorbed on internal soil particle surfaces.[15] The rapid replacement of air with water breaks apart soil aggregates,[7] increasing the erodibility of the soil. Preliminary results from a southern Idaho field study showed that soil erosion from initially dry furrows was greater than erosion from furrows that were pre-wet by drip irrigation. The hydraulics of rill flow from rain differ from furrow irrigation. Rill flow rate tends to increase downstream as additional rain water plus sheet and rill flow combine. During furrow irrigation, flow rate decreases with distance down the furrow as water infiltrates and increases with time as infiltration rate decreases which changes sediment detachment and transport capacities with distance and time. The duration of furrow irrigation runoff (typically 12 h or more) is generally longer than most rain runoff events. Temporal changes in infiltration, soil and water temperature, rill size and shape, and soil erodibility become more important for longer runoff events. Sediment concentration tends to decrease with time during furrow irrigation. Flow rate, however, increases with time, which should increase sediment detachment and transport. This indicates that soil erodibility decreases during furrow irrigation by phenomena such as armoring, surface sealing, or other unrecognized processes. Predicting small erosion events is important for irrigation. Seasonal irrigation-induced erosion occurs during numerous controlled and often small events rather than during one or two large erosion events. In southern Idaho for example, a cornfield may be sprinkler irrigated 15 to 20 times or furrow irrigated six to eight times during the growing season. The magnitude of a single irrigation erosion event is usually much smaller and less dramatic than erosion from a single 50-mm
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thunderstorm occurring on freshly tilled soil without an established crop. However, the cumulative soil loss from irrigation during the growing season may be substantial. Chemical quality of rainfall varies less from location to location than surface water and groundwater quality. Irrigation water quality can also vary during the season as return flow is added to surface water sources or as groundwater and surface water sources are mixed. Water quality can significantly impact erosion from furrow and sprinkler-irrigated fields. Increasing electrical conductivity (EC) tends to decrease erosion whereas increasing sodium adsorption ratio (SAR) tends to increase erosion.[16,17] Interactions among EC, SAR, clay flocculation, soil chemistry, rainfall application rate, etc. influence the effects of water quality on infiltration and erosion.
REFERENCES 1. Kendall, H.W.; Pimentel, D. Constraints on the expansion of the global food supply. Ambio 1994, 23 (3), 198–205. 2. Food and Agriculture Organization. FAOSTAT– Agriculture Data. Food and Agriculture Organization On-line Database; apps.fao.org (accessed Sept. 2000). 3. Tribe, D. Feeding and Greening the World, the Role of Agricultural Research; CAB International: Wallingford, Oxon, United Kingdom, 1994. 4. National research council. In A New Era for Irrigation; National Academy Press: Washington, DC, 1996; 203 pp. 5. United States Department of Agriculture. 1998 Farm and Ranch Irrigation Survey. National Agricultural Statistics Service; www.nass.usda.gov=census= (accessed Sept. 2000).
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6. Food and Agriculture Organization. AQUASTAT— Country Profiles. Food and Agriculture Organization Online Database; www.fao.org=WAICENT=FAOINFO= AGRICULT=AGL=AGLW=aquastat (accessed Sept. 2000). 7. Carter, D.L. Soil erosion on irrigated lands. In Irrigation of Agricultural Crops; Agronomy Monograph no. 30; Stewart, B.A., Nielson, D.R., Eds.; Am. Soc. Agronomy: Madison, WI, 1990; 1143–1171. 8. Koluvek, P.K.; Tanji, K.K.; Trout, T.J. Overview of soil erosion from irrigation. J. Irr. Drain. Eng. 1993, 119 (6), 929–946. 9. Israelson, O.W.; Clyde, G.D.; Lauritzen, C.W. Soil Erosion in Small Irrigation Furrows; Bull. 320 Utah Agr. Exp. Sta.: Logan, UT, 1946. 10. Mech, S.J. Effect of slope and length of run on erosion under irrigation. Agr. Eng. 1949, 30, 379–383. 11. Berg, R.D.; Carter, D.L. Furrow erosion and sediment losses on irrigated cropland. J. Soil Water Cons. 1980, 35 (6), 267–270. 12. Trout, T.J. Furrow irrigation erosion and sedimentation: on-field distribution. Trans. of the ASAE 1996, 39 (5), 1717–1723. 13. Carter, D.L.; Berg, R.D.; Sanders, B.J. The effect of furrow irrigation erosion on crop productivity. Soil Sci. Soc. Am. J. 1985, 49 (1), 207–211. 14. Thompson, A.L.; James, L.G. Water droplet impact and its effect on infiltration. Trans. of the ASAE 1985, 28 (5), 1506–1510. 15. Kemper, W.D.; Rosenau, R.; Nelson, S. Gas displacement and aggregate stability of soils. Soil Sci. Soc. Am. J. 1985, 49 (1), 25–28. 16. Lentz, R.D.; Sojka, R.E.; Carter, D.L. Furrow irrigation water-quality effects on soil loss and infiltration. Soil Sci. Soc. Am. J. 1996, 60 (1), 238–245. 17. Kim, K.-H.; Miller, W.P. Effect of rainfall electrolyte concentration and slope on infiltration and erosion. Soil Technology 1996, 9, 173–185.
Irrigation: Historical Perspective Robert E. Sojka David L. Bjorneberg J. A. Entry United States Department of Agriculture-Agricultural Research Service (USDA-ARS), NWISRL, Kimberly, Idaho, U.S.A.
INTRODUCTION Irrigation can be broadly defined as the practice of applying additional water (beyond what is available from rainfall) to soil to enable or enhance plant growth and yield, and, in some cases, the quality of foliage or harvested plant parts. The water source could be groundwater pumped to the surface, or surface water diverted from one position on the landscape to another. Development of irrigation water often entails development of large-scale, geographically significant dams and water impoundments and=or diversions that can provide additional functions apart from crop growth enhancement, e.g., flood control, recreation, or generation of electricity. In many cases sustainable irrigation development requires concomitant development of surface and=or subsurface drainage.
ANCIENT ORIGINS AND IMPORTANCE Irrigation may be the single most strategically important, intentional, environmental modification humans have learned to perform. While irrigation’s impact has not always been as critical to the global agricultural economy and food supply as it is today, it has always had major local impacts and profound historical and social consequences. In the Bible’s book of Genesis, we are told that God’s creation of humans was accompanied shortly thereafter by His assignation to Adam of the stewardship of the irrigated orchard that was Paradise. The four life-giving water heads of Judeo-Christian Paradise are also mentioned in the 47th Sura of the Koran.[1] Some anthropologists and historians point to the development of irrigation as the catalyst for the interaction of engineering, organizational, political, and related creative or entrepreneurial skills and activities which produced the outcome referred to as ‘‘civilization.’’[2–5] In the ancient Persian language, the word ‘‘abadan,’’ civilized, is derived from the root word ‘‘ab,’’ water.[1] Fundamental differences in social, cultural, religious, political, esthetic, economic, technological, and environmental outlook have been attributed to modern groupings of humankind related to their use of irrigation.[5] Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042707 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
The earliest archeological evidence of irrigation in farming dates to about 6000 B.C. in the Middle East’s Jordan Valley.[1] It is widely believed that irrigation was being practiced in Egypt at about the same time,[6] and the earliest pictorial representation of irrigation is from Egypt around 3100 B.C.[1] In the following millennia, irrigation spread throughout Persia, the Middle East and westward along the Mediterranean. In the same broad time frame, irrigation technology sprang up more or less independently across the Asian continent in India, Pakistan, China, and elsewhere. In the New World the Inca, Maya, and Aztec made wide use of irrigation. The technology migrated as far North as the current southwestern U.S.A., where the Hohokam built some 700 miles of irrigation canals in what is today called as central Arizona to feed their emerging civilization, only to mysteriously abandon it in the 14th century A.D.[3] In the ancient world, the level of irrigation sophistication varied from one setting to the next. The differences, however, stemmed mostly from variations in understanding of both large- and small-scale hydraulic principles, as well as the capabilities to construct feats of hydraulic engineering. The Assyrians, for example, built an inverted siphon into the Nineveh Aqueduct 700 years before the birth of Christ, an engineering feat unrivaled until the 1860 construction of the pressurized siphons of the New York Aqueduct.[3] Some ancient irrigation schemes have survived to the present day where geologic, soil, and climatic conditions were favorable and where then-known management principles were adequate for the prevailing conditions. However, some ancient schemes failed. In the Mesopotamian Valley, Syria, Egypt, and other areas throughout the Middle East, there were many cases where the principles of salt management and drainage were insufficiently understood, resulting in eventual permanent impairment of the land.[1] Siltation of ancient dams and reservoirs is a testament to inadequate soil conservation measures that eventually reduced the productivity of the land as well as destroyed the capacity of reservoirs to provide an adequate supply of water.[3] Erosion of irrigation channels, in geologically unstable areas like the Chilean deserts, and catastrophic failure of irrigation channels after 945
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earthquakes often defeated the best efforts of ancient engineers to maintain water supplies.[3] Modern irrigation technology probably began with the Mormon settlement of the Utah Great Salt Lake Basin in 1847, and their eventual cultivation of nearly 2.5 million ha irrigated across the intermountain western U.S.A. by the turn of the century. Whereas relationships of mass, energy, and turbulence of flow were mastered at remarkably high levels of proficiency in ancient cultures, understanding of chemistry and physico-chemical interactions of soil and salt-bearing water was relatively meager even into the 19th century.
MODERNIZATION OF IRRIGATION The mid-19th century marked a conjunction of several ascending areas of scientific learning, including chemistry, physical chemistry, physics, mineralogy, and biology. These were adapted, blended, and applied in important emerging new subdisciplines of soil chemistry, soil physics, plant physiology, and agronomy, whose fundamental principles were to prove essential for sustainable irrigation system design and operation. In ancient irrigation developments, soils, climate, and water quality were used in more forgiving combinations at some locations than at others. Where seasonal rains provided leaching, where soils were permeable and well drained, and=or where irrigation water had favorable combinations of electrolyte concentrations and specific cations, irrigation has continued to the present day, even without sophisticated management. In other areas, salinization, increased soil sodicity, and elevated water tables have limited the life spans of irrigation schemes or impaired their productivity. As irrigation moved into more marginal settings, with less productive soils, poorer drainage, and greater salinity and sodicity problems, the success or failure and ultimate longevity of the schemes became more dependent on knowledgeable application and adaptation of scientific principles. America’s Mormon pioneers, choosing to settle in a remote saltimpaired desert habitat, were forced of necessity to use trial and error and the enlightened application of all available new knowledge to reclaim their lands from the desert and to practice a sustainable irrigated crop husbandry. They were so successful in their efforts that their approaches to irrigation and saltthreatened arid land reclamation and management provided the guiding principles for development of irrigation throughout the western U.S.A. from 1902 (with passage of the Reclamation Act) to the close of the 20th century.[3] The science of irrigated agriculture and arid zone soil science, in general, relied mostly on the foundation and contributions stemming from
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Irrigation: Historical Perspective
these mid-19th century origins.[7] Development of irrigation in the western U.S.A. was further spurred by passage of the Desert Land Act of 1877 and the Carey Act of 1894, which provided land for settlement and governmental infrastructure for development. The first university level irrigation course is believed to have been taught by Elwood Mead (Lake Mead’s namesake) at the Agricultural College of Colorado in Fort Collins, Colorado.[8] Mead later took positions with the United State Department of Agriculture and eventually was a commissioner for the Bureau of Reclamation. Worldwide, many of the practical modern principles of irrigation system design and irrigated soil management can be traced to the lessons learned in the settling of the American west from 1847 to the close of World War II, when the total irrigated area in U.S.A. had grown to 7.5 million ha.[6] Following World War II, irrigation development worldwide entered a heady period of rapid expansion. World populations were increasing, in part because of increased life expectancies resulting from new medicines and use of dichlorodiphenyltrichloro ethane (DDT) to control malaria and other disease carrying insects. The advances in technology spurred by the first and second world wars were being applied to all avenues of life including agriculture. Electrical, steam, and internal combustion power sources became available to pump and pressurize water. New pump designs, the patenting of the center pivot and other sprinkler delivery systems came together in a few short decades between and immediately following the wars to revolutionize the ability to deliver water.[7]
CURRENT STATUS In the U.S.A., Soviet Union, Australia, and Africa huge government-sponsored programs were initiated in the 1930s, 1940s, and 1950s to build dams for hydropower, flood control, and irrigation, and to encourage settlement and stabilization of sparsely populated frontiers. The worldwide total irrigated area was about 94 million ha in 1950 and grew to 198 million ha by 1970.[9] In contrast, the world total irrigated area grew to only about 220 million ha by 1990[9] and to 263 million ha by 1996.[10] Not surprisingly, the easiest, least technically challenging, and least expensive irrigation developments occurred first, and more difficult, more technically challenging, more expensive projects dominate the remaining potential for water development. In some instances, dams, and large-scale water development projects have been hampered by poor economies and the instability of the countries in the potential development areas, rather than by the cost or technical challenges per se.
Irrigation: Historical Perspective
Today 60% of the earth’s grain production and half the value of all crops harvested result from irrigation.[10] Perhaps most remarkable is the agricultural production efficiency that irrigation provides worldwide. Some 50 million ha of the earth’s most productive irrigated cropland (4% of the earth’s total cropland) produces a third of the entire planet’s food crop.[11] Hectare for hectare, irrigated land produces two to two and a half times the yield and three times the crop value per hectare compared with nonirrigated land.[10,12,13] Yet, the irrigated portion amounts to only about one sixth of the world’s total cropped area[14] and about 5% of the world’s total production area, which includes cropland, range, and pasture.[15] In U.S.A., most fresh fruits and vegetables in grocery stores come from irrigated agriculture. Beyond survival and economic impact, even our entertainment and esthetics rely heavily on irrigation. Nearly allgarden nursery stock in U.S.A. is propagated and maintained under irrigation and today’s parks, play fields, golf courses, and commercial landscaping are seldom established and maintained without irrigation. To put the global production impact of irrigated agriculture in perspective, it would require over quarter billion hectares of new rainfed agricultural land (an area the size of Argentina) to supply the average additional production that irrigation’s high yield and efficiency provides. Actually, this estimate is conservative. If the land currently irrigated was no longer irrigated but left in production, its output would be well below the mean of existing rainfed land; this is because the lion’s share of irrigation occurs in arid or semiarid environments. Furthermore, additional rainfed land brought into production to replace irrigated agriculture would be well below the current rainfed average productivity; this is because the rainfed land with greatest yield potential has already been brought into production. A more realistic estimate might be double or triple the quarter billion hectare nominal replacement estimate. In a world of six billion people, irrigation has become essential by providing yet another benefit that cannot be immediately quantified, but which is as important as or more important than production efficiency or economic gain, or even the often uncredited benefits in many irrigation development schemes of hydropower, flood control, transportation, and rural development. The overriding benefit is security— security derived from food production stability. Substantial portions of the world food supply are subject to precipitous and often unpredictable yield reductions owing to drought. Irrigation was a key component of the ‘‘Green Revolution’’ of the 1960s and 1970s, which stabilized food production in the developing world, providing a new tier of nations the opportunity to turn some of their monetary and human resources to
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nonagricultural avenues of economic and social development. Much of the drop in the rate of increase of worldwide food production in the last two decades relates to the decrease in the rate of irrigation development since 1980.
ISSUES AFFECTING THE FUTURE Although there are large projects currently underway or planned for the near future, notably in China, Pakistan, Brazil, Canada, Spain, and Portugal, the equal of the great dam building era from 1930 to 1970 will likely never be seen again. Much of the development of irrigation in the last decade has been achieved through exploitation of groundwater or by smaller scale entrepreneurial surface water developments. In Australia, for example, with the disastrous deflation of the world wool market in the 1990s, substantial numbers of individual sheep stations ceased raising animals and developed their surface water supplies to grow vast hectares of irrigated cotton and rice. Worldwide, further expansions in irrigated area are unlikely to be large because of the limited remaining surface water sources to exploit and because of the growing environmental concerns, especially related to soil waterlogging, salinization, and sodication problems. Future increases in irrigated area will likely result mainly from the development of the so-called ‘‘supplemental’’ irrigation in humid rainfed areas, from improvements in water use efficiencies associated with utilization of existing irrigation resources, and from improvements in the reuse of municipal, industrial, and agricultural wastewaters. Howell[10] noted that improved efficiencies have resulted in a reduction in the mean applied depth of water in the U.S.A. from about 650 mm annually in 1965 to 500 mm currently. These increased efficiencies have come in great part from the improved understanding of the energy physics of water which led to modern evapotranspiration (ET) theory and ET-based crop irrigation scheduling.[9,10] Many other water conservation practices were developed in the last half of the 20th century, including drip and microirrigation, which have spread from the hyperxeric conditions of Israel in the early 1950s[1] to nearly every climate and rainfall environment where there is a need, for one reason or another, to conserve water. Loss of productive capacity caused by soil salinization, sodication, and waterlogging, as well as by runoff contamination, riparian habitat impairment, and species losses, are often cited by critics of irrigation as evidence of fundamental drawbacks of irrigated agriculture. Surveys have indicated that of the existing irrigated lands, some 40–50 million ha show measurable degradation from waterlogging, salinization, and sodication.[16,17] Erosion and sedimentation of reservoirs
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and channels caused the failures of ancient irrigation schemes and have limited the life expectancy of some modern dams to only a few decades as well.[3,18] These problems should not be trivialized. They demonstrate the need for intensified research and conservation, as well as improved dissemination and use of known prophylactic and remedial technologies. However, neither should they be overstated nor presented without due consideration of mitigating factors. If rates of production loss from these problems are weighted by relative yield or economic value of irrigation compared to rainfed agriculture, and if other positive effects of irrigation are considered, the relative magnitude of negative impacts of irrigation is greatly diminished. For example, runoff contamination from irrigated land would have to be three times the mean for rainfed land, on a crop value basis, or two to two and a half times the mean, on a yield basis, to be ‘‘comparable’’ to problems from nonirrigated agriculture because of the respective relative efficiencies of irrigated agriculture. Both the absolute and relative areas of impaired production, plus the degree of impairment, need to be compared on a global basis to rainfed losses, as well as the potential for remediation and production expansion under either circumstance. Positive impacts of irrigation water development include many social and economic benefits such as hydropower, flood control, transportation, recreation, and rural development. Positive environmental effects result from crops, field borders, canals, ditches, and reservoirs that provide significant expansions of habitat for a variety of wildlife compared to undeveloped arid land. As with all agriculture methods in recent years, irrigated agriculture has greatly improved its ability to provide humanity’s essential needs in closer harmony with environmental needs. This remains a key priority in modern irrigated agricultural research along with continued improvement of production potential to meet the needs of a growing population. Population growth is occurring mostly in underdeveloped nations, where there is an added expectation of improved diet and standard of living. This expectation raises the need for improved production per capita above a simple linear extrapolation based on population. Only high yield intensive production from irrigated agriculture has shown the potential to meet these projected needs. The knowledge and technology exist to design and operate irrigated agricultural systems sustainably, and without environmental damage or irreversible soil impairment.[9,16,19] The problem lies in implementing known scientific principles and technologies in a timely fashion as part and parcel of irrigation project and system design and management. This is true both on a regional or project basis and at the farm or field level. Politics and economics play pivotal roles in how wellknown science and technology are applied. In this
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respect irrigated agriculture is no different than the myriad manifestations of rainfed agriculture, or any other environmentally impacting activity. Because of modern political and economic considerations, there is usually great pressure, when designing and developing a large-scale irrigation project, to allocate resources for development of as many irrigated hectares as possible at the outset. This often occurs without provision of an adequate technical or social support network to the farming community making the transition to irrigated agriculture. Many schemes fail to provide sufficient financial or technical resources to install drainage systems, to educate farmers, or to include them in policy formulation. The resources are needed to help guarantee prudent water application and salinity or drainage management compatible with the social, technical, and financial capabilities of the water users. These are not failures of irrigation. They are failures of human institutions. In this respect, human political, economic, and institutional considerations rather than technical advances or water availability may represent the real challenges for irrigation in the 21st century. These obstacles must be overcome if irrigated agriculture is to provide the production advantage required to satisfy future human needs and to meet improved dietary and living standard expectations.
REFERENCES 1. Hillel, D. Rivers of Eden: the Struggle for Water and the Quest for Peace in the Middle East; Oxford University Press: New York, 1994; 355 pp. 2. Mitchell, W. The hydraulic hypothesis. Curr. Anthropol. 1973, 14, 532–534. 3. Reisner, M. Cadillac Desert: the American West and its Disappearing Water; Penguin Books: New York, 1986; 582 pp. 4. Wittfogel, K.A. Oriental Despotism: a Comparative Study of Total Power; Yale University Press: New Haven, CT, 1956. 5. Worster, D. Rivers of Empire: Water, Aridity & the Growth of the American West; Pantheon Books: New York, 1985; 402 pp. 6. Hoffman, G.J.; Howell, T.A.; Solomon, K.H. Introduction. In Management of Farm Irrigation Systems; Hoffman, G.J., Howell, T.A., Solomon, K.H., Eds.; American Society of Agricultural Engineers: St. Joseph, MI, 1990; 5–10. 7. Morgan, R.M. Water and the Land, a History of American Irrigation; The Irrigation Association: Fairfax, VA, 1993; 208 pp. 8. Heerman, D.F. Where we have been, what we have learned and where we are going. In National Irrigation Symposium, Proceedings of the 4th Decennial Symposium; Evans, R.G., Benham, B.L., Trooien, T.P., Eds.; American Society of Agricultural Engineers: St. Joseph, MI, 2000; 40–51.
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9. Jensen, M.E.; Rangeley, W.R.; Dieleman, P.J. Irrigation trends in world agriculture. In Irrigation of Agricultural Crops; Stewart, B.A., Nielsen, D.R., Eds.; Agronomy Monograph 30; American Society of Agronomy: Madison, WI, 1990; 31–67. 10. Howell, T.A. Irrigation’s role in enhancing water use efficiency. In National Irrigation Symposium, Proceedings of the 4th Decennial Symposium; Evans, R.G., Benham, B.L., Trooien, T.P., Eds.; American Society of Agricultural Engineers: St. Joseph, MI, 2000; 66–80. 11. Tribe, D. Feeding and Greening the World, the Role of Agricultural Research; CAB International: Wallingford, UK, 1994; 274 pp. 12. Bucks, D.A.; Sammis, T.W.; Dickey, G.L. Irrigation for arid areas. In Management of Farm Irrigation Systems, ASAE Monograph; Hoffman, G.J., Howell, T.A., Solomon, K.H., Eds.; American Society of Agricultural Engineers: St. Joseph, MI, 1990; 499–548. 13. Kendall, H.W.; Pimentel, D. Constraints on the expansion of the global food supply. Ambio 1994, 23 (3), 198–205.
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14. Gleick, P.H. Water in Crisis: a Guide to the World? Fresh Water Resources; Oxford University Press: New York, 1993; 473 pp. 15. Food and Agriculture Organization. FAOSTAT— Agriculture Data, Food and Agriculture Organization On-Line Database. http:==apps.fao.org (accessed September 2000). 16. Rhoades, J.D. Sustainability of irrigation: an overview of salinity problems and control strategies. Pp1–42. In CWRA 1997, Annual Conference on Footprints of Humanity: Reflections on Fifty Years of Water Resource Developments, Lethbridge, Alta, June 3–6, 1997. 17. Ghassemi, F.; Jakeman, A.J.; Nix, H.A. Salinization of Land and Water Resources, Human Causes, Extent, Management, and Case Studies; CAB International: Wallingford, U.K., 1995. 18. Fukuda, H. Irrigation in the World; University of Tokyo Press: Tokyo, 1976. 19. Sojka, R.E. Understanding and managing irrigationinduced erosion. In Advances in Soil and Water Conservation; Pierce, F.J., Frye, W.W., Eds.; Sleeping Bear Press: Ann Arbor, MI, 1998; 21–37.
ISRIC: World Soil Information David Dent ISRIC–World Soil Information, Wageningen, The Netherlands
INTRODUCTION ISRIC–World Soil Information is an independent foundation, funded by the Netherlands Government with a mandate to increase knowledge of the land, its soils in particular, and to support the sustainable use of land resources; in short, to help people understand soils. Its aims are to
Inform and educate, through the World Soil Museum.
Maintain and disseminate data for the scientific community through the ICSU World Data Centre for Soils which is the custodian of global and regional datasets, land resources maps, and reports; for many of these, ISRIC is the sole repository.
Conduct applied research on land resources and their management and to support the development of national and international policy. The institute has a tradition of welcoming guest researchers.
The multilingual staff has expertise in taxonomy of soils, soil survey, land evaluation and land use planning, soil and water conservation, soil fertility, and data management and interpretation—globally and especially in tropical regions.
HISTORY On the initiative of Professor F. A. van Baren, the International Society of Soil Science promoted the establishment of an international museum of soil standards to collect, analyze, and display the soils of the world, as depicted in the FAO-UNESCO Soil Map of the World. This was adopted by the General Council of UNESCO in 1964 and support was offered by the Government of The Netherlands. The institute was founded in 1966 with working funds provided by the Ministry of Education, Culture and Sciences of The Netherlands, and administered by the International Institute for Aerospace Survey and Earth Sciences (ITC) in Enschede. At first, facilities were provided by the University of Utrecht; in 1977, the present premises—which comprise the staff quarters, laboratory, workshop, teaching and conference facilities, and the world soils exhibition—in Wageningen 950 Copyright © 2006 by Taylor & Francis
were provided by the Netherlands Directorate General of International Cooperation. In line with its evolving mandate and activities, the institute was renamed International Soil Reference and Information Centre (ISRIC) in 1974; it became a foundation with its own statues and Board of Governors in 1995, registering the logo ISRIC–World Soil Information in 2004. The business arrangement with ITC was dissolved in 2002 and a cooperative agreement concluded with Wageningen University and Research Centre. It has a memorandum of understanding with FAO, including a joint program of work; close working relations are also maintained with UNESCO, United Nations Environment Programme (UNEP), and United Nations Convention to Combat Desertification (UNCCD).
WORLD SOIL MUSEUM The World Soil Museum is the focus of an active educational program. Groups and individuals are welcome to the well-documented, thematic exhibition of soil monoliths, representing the major soils of the world, their landscape relationships, and management. Several monoliths are on loan to museums and universities around the world (Figs. 1–4). A new initiative, the ISRIC World of Soils, makes available through the Internet a wide range of educational resources: programs, pictures, data, and text. A UNESCO Chair in Land Resources is proposed as an international focus for soils education, to include current ISRIC courses in taxonomy, soil survey, land evaluation, and land use planning, and database management and contributions from several partner institutions in The Netherlands and Switzerland. Publications program includes new and updated standard technical works—in 2005 new editions of the FAO Guidelines for soil profile description and the Booker Soil Manual—and ISRIC Reports, which are available both online and in paper copy.
WORLD DATA CENTRE FOR SOILS The World Data Centre for Soils serves the scientific community under the auspices of the International Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120041260 Copyright # 2006 by Taylor & Francis. All rights reserved.
ISRIC: World Soil Information
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Fig. 1 Collecting a soil monolith. (View this art in color at www.dekker.com.)
Fig. 3 Teaching in the World Soil Museum. (View this art in color at www.dekker.com.)
Council for Science (ICSU). Its role is to collect, scrutinize, analyze, and disseminate data and information worldwide, in particular to ICSU programs in global change, climate, and the environment. Data from ICSU programs are maintained and made freely available; a major project is under way to digitize the datasets and maps to make them available through the Internet or on DVD. The principal holdings are
domain, compiled for global climatic change studies and backed up by a working database of more than 9500 profiles.
The Global Soil and Terrain (SOTER) datasets for South and Central America, Central and Eastern Europe, and Southern and Eastern Africa: spatial mapping units and geo-located point data at scales from 1 : 1 million to 1 : 5 million, available online.
Soil and water conservation database of the World Overview of Conservation Approaches and Technologies (WOCAT).
Monolith collection of more than 900 profiles, supported by some 5000 reference samples, fully analyzed by standard methods, representing the mapping units of the FAO-UNESCO Soil map of the world[1,2] and now being extended to encompass the groups and lower-level units of the World Reference Base for Soil Resources.[3]
ISRIC soil information system (ISIS) dataset, currently 800 profile descriptions with complete, validated, laboratory data, available online in SQL.
World Inventory of Soil Emission Potentials (WISE) dataset of 4000 profiles in the public
Fig. 2 Preparation of monolith in the workshop. (View this art in color at www.dekker.com.)
Copyright © 2006 by Taylor & Francis
For micromorphology, the following soil collections are available:
Systematic collection of 3500 large thin sections from the ISIS profiles.
STIBOKA-Jongerius collection of 10,000 large thin sections, mainly of Dutch soils.
Schmidt–Lorenz collection of more than 15,000 small thin sections of soils, mainly from Europe, Africa, Asia, and Australia.
Fig. 4 Display of monoliths. (View this art in color at www.dekker.com.)
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Fig. 5 Soil Map of the World. (View this art in color at www.dekker.com.)
Fig. 6 A) and B) SOTER units are tracts of land with a distinctive, often repetitive, patterns of landform, slope, parent material, and soils. (View this art in color at www.dekker.com.)
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ISRIC: World Soil Information
Table 1 Data held in ISIS and WISE datasets: attributes of the ISIS database No. of profiles
No. of countries
Environmental characteristics
Site characteristics
Soil morphology
Physical attributes
Chemical attributes
880
81
Physiography Geology Hydrology Climate Vegetation
Surface conditions Slope Land use Human influence Crops
Horizons Color Texture Structure Consistence Cutans Nodules Coarse fragments Biological and plant activity Porosity Pans Wageningen Permeability
Particle-size distribution Water-dispersible clay Bulk density Water retention
PH Organic C Organic N CaCO3 CaSO4 Exchangeable cations Cation exchange capacity (CEC) Exchangeable Al, H Extractable Fe, Al, Si, P soluble salts Elemental composition
Mineralogical attributes
Additional information
Clay mineralogy Sand mineralogy Heavy minerals
Thin sections Photographs Soil and soil-related maps Reports Reference soil samples Classification: local, FAO, Soil Taxonomy and World Reference Base
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ISRIC: World Soil Information
Fig. 7 Global SOTER coverage, December 2004. (View this art in color at www.dekker. com.)
There are excellent facilities for micromorphological examination and a common catalog is in preparation to make the collections publicly accessible. The World Data Centre maintains a systematic collection of soil maps (6000): reports, specialist texts, grey literature, and journals that hold important contributions to soil literature, especially from tropical countries (17,000 titles), and 15,000 transparencies. Valuable gifts have been received from individual researchers and universities. The library and map holdings may be searched through the Wageningen University catalog (http:==library.wur.nl=isric=).
NDVI imagery to identify and delineate hotspots for further characterization by 30 m-definition Landsat imagery and subsequent field measurements by national teams; a policy initiative, Green Water Credits—akin to the Kyoto Protocol carbon credits mechanism—to build a global facility to pay rural land managers for water management services that are at present unrecognized and unrewarded, relieving poverty and enabling food and water security for everyone; and linking the SOTER and WOCAT databases with social rules to identify best-bet management practices and provide a learning network to support their application.
APPLIED RESEARCH The institute is well known for underpinning the Soil Map of the World, the Global Assessment of Human-induced Soil Degradation (GLASOD)[4] produced for the Rio Conference in 1992, the World Reference Base for Soil Resources (since 1980), the SOTER database,[5] and for interpretations of this information for land use planning and, most recently, in terms of sources and sinks of greenhouse gases. (Figs. 5–7; Table 1). The institute is also a partner in the WOCAT (www.wocat.net). The trends in research over recent decades have been shifting away from data collection and toward putting the data to work and from solo soil science to work within multidisciplinary, international teams. An example is the recently concluded study on the Pan-European Soil Erosion Assessment.[6] Current and future priorities include the following: a quantitative Global Assessment of Land Degradation and Improvement (GLADA), using 8 km-definition satellite
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REFERENCES 1. FAO-UNESCO. In Soil Map of the World, 1:5M; UNESCO: Paris, France, 1974–1981; vols. I–X. 2. FAO-UNESCO-ISRIC. In Revised Legend of the Soil Map of the World. World Soil Resources Report No. 60; FAO: Rome, 1990. 3. FAO-ISRIC-ISSS. In World Reference Base for Soil Resources. World Soil Resources Report No. 84; FAO: Rome, 1998. 4. Oldeman, L.R.; Hakkeling, R.T.A.; Sombroek, W.G. World Map of the Status of Human-induced Soil Degradation; ISRIC-UNEP: Wageningen, 1990. 5. van Engelen, V.W.P.; Wen, T.T. Global and National Soils and Terrain Digital Databases (SOTER): Procedures Manual, Revised; ISRIC: Wageningen, 1995. 6. Mantel, S.; van Lynden, G.J.; Huting, J. Pan European Erosion Assessment (PESERA), Work Package 6: Scenario analysis. Final report: April 2003–September 2003, Hungary; ISRIC–World Soil Information: Wageningen, 2003.
Jhum/Shifting Agriculture P. S. Ramakrishnan School of Environmental Sciences, Jawaharlal Nehru University, New Delhi, India
INTRODUCTION The forest farmer in the tropics has managed the traditional shifting agriculture (slash-and-burn agriculture, locally known in India as jhum), which is essentially an agroforestry system organized both in space and time for centuries. The small-scale perturbations, in the past, ensured enhanced biological diversity in the forest, with enriched crop and associated biodiversity, capitalizing on the nutrient released through slashand-burn. With increasing pressure on forest resources from outside and on population pressure from within, and the consequent declining soil fertility through land degradation, agricultural cycle has shortened. It is suggested[1] that, in the late 1980s, about 500 million people were dependent on shifting agriculture in 90 countries, covering an area of approximately 400 million hectares of tropical forest land area (Table 1). A subsequent forest resource assessment[2] found that more than 7% of the 1980 forest area underwent change during the period 1980–1990, with more than half of this change due to shifting agriculture, resulting in moderate to severe degradation. The net consequence is drastic reduction in shifting agricultural cycle, leading to: 1) drastic yield reduction; 2) reduced system stability and resilience, leading to social disruption; 3) biodiversity decline because of weed takeover, biological invasion, and=or eventual site desertification; and 4) substantial CO2 emitted into the atmosphere. All attempts made so far in finding an alternate to shifting cultivation, for want of a holistic approach in dealing with the complex issues, have had little or no impact on the farmer.[3] It is in this context that an evaluation of ecological impacts and the finding of an acceptable but sustainable solution(s) to the problem become critical.
SOIL FERTILITY AND NUTRIENT BUDGET UNDER SHIFTING AGRICULTURE Shifting agriculture is largely confined to the humid tropics of Asia, Africa, and South America, with highly variable Oxisols, Ultisols, Inceptisols, and Entisols, where the major soil constraint is the presence of some toxic chemicals with low nutrient reserves.[4] The complex tropical rain forests are often extremely Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120016599 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
fragile. First, these forests, which have developed over centuries, often grow on highly infertile soil, with biomass as the chief storage compartment for nutrients. Second, in oligotrophic areas, stability is ensured by the presence of a thick surface root mat, which picks up nutrients released from decaying leaf litter on the mineral soil and pumps these nutrients back into the living biomass before they have the chance to enter the mineral soil. Frequent and large-scale perturbations, as are occurring now, upset this delicate balance in nutrient cycling. In general, nitrogen (N) and potassium (K), being very labile, are often limiting under many situations. Phosphorus (P) deficiency is a widely reported soil constraint in tropical America, which is further compounded by high P fixation related to soil acidity. There are also other problems related to soil acidity– low availability of calcium (Ca) and magnesium (Mg), often times with aluminum (Al) and manganese (Mn) toxicities. After clear-cutting and burning of the forest, the ecosystem loses its ability to hold nutrients. Losses occur through the volatilization of carbon (C) and N during the burn. Substantial nutrient losses through wind blowing of ash, runoff, and leaching through water may all occur before adequate vegetal cover builds up, during both the cropping and fallow phases. During the cropping phase, losses also occur through the uptake and removal of nutrients through biomass that gets harvested. A reduced cycle length (5 years or less) in many parts of the world has led to a drastic decline in soil fertility under short agricultural cycles imposed on the same site over a period of time (Table 1). Largely herbaceous vegetation that develops under very short cycles of 5 years or so does not help in adequate regeneration of the lost soil fertility. The rapid regeneration of forest vegetation following clearing and burning reduces nutrient loss and allows a return to the steady state cycling characteristics of mature forests. Although farmers deal with the decline in soil fertility in different ways, a minimum of 10–15 years is required for fallow regrowth in order to recoup most of the soil fertility lost during the cropping phase (Fig. 1). The C sequestration in the system depends largely on the cycle length of these systems,[1] as also observed in the Indonesian case study.[5] The N budgeting under different cycle lengths of 15, 955
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Table 1 Forest fallows (thousands of hectares) under shifting agriculture in the late 1980s Closed forest fallows
Open forest fallows
108,600
61,650
Africa
61,700
104,350
Asia
69,250
4,000
239,550
170,000
Region South America and the Pacific
(e.g., northeastern India). The consequence of this is less land area of shifting agriculture and a further shortening of the cycle. Therefore, the success of shifting agriculture is, to a large extent, related to nutrient cycling patterns and processes of the forest fallow phase.
(From Ref. .)
KNOWLEDGE SYSTEMS FOR LAND USE MANAGEMENT
10, and 5 years is illustrative of the kind of issues involved (Table 2). During one cropping phase, the agroecosystem loses about 600 kg ha1 N (the difference between the soil N capital before and after one cropping). With the plot under a 5-year cycle having the same cycle length during the last 20 years, this system had lost 1.28 103 kg ha1 N from its initial capital of 7.68–6.40 103 kg ha1. While 10and 15-year agricultural cycles are long enough to restore the original N status in the soil before the next cropping, it seems unlikely that the 600 kg ha1 N lost during one cropping could be restored under a 5-year cycle—an observation similar to other nutrients, too, such as K. The increased frequency of fire and cropping, with too short a fallow phase, thus results in rapid site degradation. The first step in site degradation is the replacement of forests by an arrested weed stage. Large tracts of forested lands in the Asian tropics, for example, are taken over by the grass Imperata cylindrical (thatching grass, locally known in the Asian region as ‘‘alangalang’’). Exotic weed invasion is yet another major consequence of frequent perturbation under short agricultural cycles in many parts of the world, with consequences for ecosystem processes.[6] In extreme cases, the end result is a bald, totally desertified landscape[1]
‘‘Formal’’ ecological knowledge derived through the hypothetico-deductive method—validated ‘‘traditional ecological knowledge’’ (TEK) derived largely through societal experiences and perceptions accumulated by traditional societies during their interaction with nature and natural resources—has a strong human element attached to it. This knowledge needs to be effectively integrated to ensure the participatory land use development of traditional societies.[7] Linking ecological processes with social processes is the key issue here. Thus, for example, the concept of ecological keystone, an end product of a social selection process, is illustrative of the linkages that exist between the traditional and the formal knowledge systems. Thus, in many areas in northeast India where the landscape is highly degraded, a legume crop of lesser known food value, Flemingia vestita (locally known in Megalaya, India, as ‘‘Soh-phlong,’’ yielding up to 3000 kg of edible juicy tuber), which is socially valued, is used both in space and in time under a 2- to 5-year rotational fallow system. By fixing 250 kg ha 1 yr1 N, this keystone species ensures the sustainability of these low-input agroecosystems, under conditions of extreme pressure on land under low soil fertility. Using organic residues and manipulating soil biodiversity through socially valued and ecologically important keystone
Tropical world (total) [1]
Fig. 1 Changes in cumulative quantity of available P and K within a soil column of 40 cm depth under 0-, 1-, 5-, 10-, 15-, and 50-year-old jhum fallows (e.g., g eq=m2).
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Table 2 Net change of N (103 kg ha1 yr1) in the soil under jhum in northeast India 5-year fallow cycle 15-year fallow cycle
10-year fallow cycle
First year crop
Second year crop
Soil pool before burning
7.68
7.74
6.40
5.98
Soil pool at the end of cropping
7.04
7.15
5.98
5.60
Net difference
0.64
0.59
0.42
0.38
(From Ref.[3].)
earthworm species, sustainable fertility management has been made possible. It is a patented technology that offers opportunities[8] for effective fallow management practices. Nepalese alder (Alnus nepalensis), a socially valued species, is another N-fixing tree conserved by traditional societies of northeast India in their shifting agricultural plots. It happens to be a socially significant keystone species. This early successional tree species in the northeastern hill region is conserved by the shifting agricultural farmer, during both the cropping and fallow phases. With its roots nodulated by Frankia, this species can fix up to about 125 kg ha1 yr1 N and has the potential to recover all the 600 kg of N lost from the system over a 5-year cycle period. It would, otherwise, take a minimum of 10 years of natural fallow regrowth to recover all these N back into the system. In other words, there is a close connection between the ecological and social dimensions of this validated TEK, and there are implications for fallow management through ‘‘incremental pathway’’ and=or ‘‘contour pathway’’ for agroecosystem redevelopment.[3,9] Adapting this knowledge to modern scientific inputs is important for community participation in soil fertility management and acceleration of the developmental process itself.
at least in the short term. Management of forest fallows[3] or grass fallows[10] seems to be an attractive cost-effective solution to the problem, as has been suggested through many studies. Such an approach forms the basis for a major initiative, which aims at redeveloping shifting agriculture in Nagaland in northeast India,[11] through a participatory process of fallow management in over 5500 replicated test plots in farmers’ fields spread across 1200 villages. The key to the management lies in appropriately constructed village-level institutions that are based on the local value system. In parts of South America (Venezuela), natural secondary forest succession has been suggested as a model to replace traditional shifting agriculture: bean (Phasolus vulgaris), corn (Zea mays), sugarcane (Saccharum officinarum), and pineapple (Ananas comosus) in the first year; followed by woody yucca (Manihot esculenta), cashew (Anacardium occidentale), or papaya (Carica papaya); followed by larger trees such as Brazil nut (Bertholletia excelsa) and jackfruit (Artocarpus sp.). At another level, the home garden concept could be the model for developing a plantation economy (found in many Asian and Latin American countries). Contour Pathway
SHIFTING AGRICULTURE AND SUSTAINABILITY Realizing that sustainable soil fertility management is the key issue for finding a solution to the vexed problem of shifting agriculture-affected areas, two different approaches are possible. If the society under consideration is more ‘‘traditional,’’ an incremental pathway is more appropriate to be able to relate to their value system. For others who are less traditional and are ready to make a more drastic departure, the contour pathway could be the solution. Incremental Pathway Building on traditional technology in an incremental fashion is one of the options for shifting agriculture,
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As a possible medium strategy, this type of management acknowledges and works with the ecological forces that provide the base on which the system must be built, while acknowledging the social, economic, and cultural requirements of the farming communities. Working with nature instead of dominating it, this approach seeks active planning, keeping in mind the nature of the background ecosystem. Slope management has long been a major element of farming in the western Pacific region and in the uplands of the Asian tropics. The Sloping Agricultural Land Technology (SALT) developed by the Mindanao Baptist Rural Life Center in the early 1980s in the southern part of the Philippines is based on planting field and perennial crops in 3- to 5-m bands between double rows of N-fixing trees and shrubs planted on contours for soil conservation.[12] The crop species and the tree=shrub species could vary. Although SALT technology has been tested successfully
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in many countries in the Asian tropics, socioeconomic and cultural problems stand in the way of its large-scale acceptance.
CONCLUSIONS Involving local communities in managing forestry and nontimber forest product-related activities for cash economy is important, as shifting agriculture cannot be viewed in isolation from forestry and forest-related activities of local communities. In the ultimate analysis, as a long-term strategy, it may be desirable to have a mosaic of agroecosystem types using all of the pathways just mentioned, along with intensive modern agricultural systems, coexisting with natural ecosystem types, managed or unmanaged. The maintenance of the overall sustainability of the system requires a patchwork mosaic that would, albeit inadvertently, be the best plan for effectively managing natural resources of the landscape, in the shifting agricultureaffected areas.
REFERENCES 1. FAO=UNEP. Tropical Forest Resources (by Jean-Paul Lanley); Forestry Paper 50; Food and Agriculture Organization (FAO): Rome, Italy, 1982. 2. FAO. Forest Resources Assessment 1990: Global Synthesis; Forestry Paper 124; Food and Agriculture Organization (FAO): Rome, Italy, 1995. 3. Ramakrishnan, P.S. Shifting Agriculture and Sustainable Development: An Interdisciplinary Study from North-Eastern India; UNESCO-MAB Series; Paris, Parthenon Publishers: Carnforth, Lancs, UK, 1992. 4. Sanchez, P.A. Soils. In Tropical Rain Forest Ecosystems; Leith, H., Werger, M.J.A., Eds.; Elsevier: Amsterdam, 1989; 73–88.
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5. Tomich, T.P.; van Noordwijk, M.; Budidaresono, S.; Gillison, A.; Kusumanto, T.; Murdiayarso, D.; Stolle, F.; Fagi, A.M. Alternatives to Slash-and-Burn in Indonesia: Summary Report and Synthesis of Phase II; ASB Indonesia and ICRAF-S.E. Asia: Bogor, Indonesia, 1998. 6. Ramakrishnan, P.S.; Vitousak, P.M. Ecosystem-level processes and consequences of biological invasions. In Biological Invasion: A Global Perspective; Drake, J.A., Mooney, H.A., di Castri, F., Groves, R.H., Kruger, F.J., Rejmanek, M., Williamson, M., Eds.; SCOPE 37; John Wiley: New York, 1989; 281–300. 7. Ramakrishnan, P.S. Ecology and Sustainable Development; National Book Trust: New Delhi, India, 2001. 8. Senapati, B.K.; Naik, S.; Lavelle, P.; Ramakrishnan, P.S. Earthworm-based technology application for status assessment and management of traditional agroforestry systems. In Traditional Ecological Knowledge for Managing Biosphere Reserves in South and Central Asia; Ramakrishnan, P.S., Rai, R.K., Katwal, R.P.S., Mehndiratta, S., Eds.; UNESCO and Oxford IBH: New Delhi, 2002; 139–160. 9. Swift, M.J.; Vandermeer, J.; Ramakrishnan, P.S.; Anderson, J.M.; Ong, C.K.; Hawkins, B. Biodiversity and agroecosystem function. In Functional Roles of Biodiversity: A Global Perspective; Mooney, H.A., Cushman, J.H., Medina, E., Sala, O.E., Schulze, E.D., Eds.; SCOPE Series; John Wiley: Chichester, UK, 1996; 261–298. 10. Lal, R.; Wilson, G.F.; Okigbo, B.N. Changes in properties of an alfisol produced by various cover crops. Soil Sci. 1979, 127, 377–382. 11. NEPED; IRRR. Building Upon Traditional Agriculture in Nagaland; Nagaland Environmental Protection and Economic Development, Nagaland India and International Institute of Rural Reconstruction: Philippines, 1999. 12. Pratap, T.; Watson, H.R. Sloping Agricultural Land Technology (SALT): A Regenerative Option for Sustainable Mountain Farming; International Centre for Integrated Mountain Development: Khatmandu, Nepal, 1994.
Land Capability Analysis Michael J. Singer University of California, Davis, California, U.S.A.
INTRODUCTION
KINDS OF SYSTEMS
All soils are not the same and they are not of the same capability for every use. Land capability implies that the choice of land for a particular use contributes to the success or failure of that use. It further implies that the choice of land for a particular use will determine the potential impact of that use on surrounding resources such as air and water. To make the best use of land and to minimize the potential for negative impacts on surrounding lands, land capability analysis is needed. The assessment of land performance for specific purposes is land evaluation.[1] A system that organizes soil and landscape properties into a form that helps to differentiate among useful and less useful soils for a purpose is land capability classification. Land capability is a broader concept than soil quality, which has been defined as the degree of fitness of a soil for a specific use.[2] Bouma[3] points out that land capability or land potential needs to be evaluated via various scales and gives the example of precision agriculture, which requires land capability analysis in more detail than that required to determine if an investment should be made to initiate agriculture. Land capability or suitability classification systems have been designed to rate land and soil characteristics for specific uses (Table 1). Huddleston[4] has reviewed many of these systems. They may also rate land qualities. Land qualities have been defined by the United Nations Food and Agricultural Organization[1] as ‘‘attributes of land that act in a distinct manner in their influence on the function of land for a specific kind of use.’’ An example of a land quality is the plant available water stored in soil, and an example of a soil characteristic is the clay content that contributes to the plant available water holding capacity. It is generally recognized that a single soil characteristic is of limited use in evaluating differences among soils,[5] and that use of more than one quantitative variable requires a system for combining the measurements into a useful index.[6] Gersmehl and Brown[7] advocate regionally targeted systems.
Land rating systems for agriculture include those that are used to evaluate the potential for agricultural development of new areas, and others that evaluate the potential for agriculture in already developed areas. Many other land capability assessments exist to help planners rate suitability of agricultural lands for nonagricultural uses. Some examples of agricultural land capability systems are described in this chapter. All systems have, in common, a set of assumptions on which the analysis is based and each system answers the question ‘‘capability for what use.’’
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001827 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
Development Potential Examples of systems designed to determine the potential for agricultural development include the FAO framework for land evaluation and the U.S. Bureau of Reclamation (USBR) irrigation suitability classification. The FAO framework combines soil and land properties with a climatic resources inventory to develop an agro-ecological land suitability assessment. The USBR capability classification was frequently used to evaluate land’s potential for irrigation in the Western U.S. during the period of rapid expansion of water delivery systems.[8–11] It combines social and economic evaluations with soil and other ecological variables to determine whether the land has the productive capacity, once irrigated, to repay the investment necessary to bring water to an area. It recognizes the unique importance of irrigation to agriculture and the special qualities of soils that make them irrigable. Land Capability The USDA Land Capability Classification (see entry by Fenton) is narrower in scope than either the FAO or USBR capability rating systems. The purpose of the Land Capability Classification (LCC) is to place arable soils into groups based on their ability to sustain common cultivated crops that do not require specialized site conditioning or treatment.[12] Nonarable soils, unsuitable for long term, sustained cultivation,
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Table 1 Examples of land capability systems System
Purpose
Property
References
FAO framework
Development potential
Used for large-scale development of agriculture
[1,10]
USBR irrigation suitability
Potential for irrigation development
Used for determining potential to repay costs of developing irrigation
[8,9]
USDA land capability classification
Land capability for agriculture
Uses 13 soil, climate, and landscape properties to determine agricultural capability
[4,12]
Storie index
Land capability for agriculture
Uses nine soil and management factors to determine agricultural capability
[17–19]
Soil potential
Soil suitability for specific uses
Uses a cost index to rate land for any potential use
[16]
Soil quality
Determining status of soil profile
Used for determining the status of selected soil properties
are grouped according to their ability to support permanent vegetation, and according to the risk of soil damage if mismanaged. Several studies have shown that lands of higher LCC have higher productivity with lower production costs than lands of lower LCC.[13–15] In a study of 744 alfalfa-, corn-, cotton-, sugar beet- and wheat-, growing fields in the San Joaquin Valley of California, those with LCC ratings between 1 and 3 had significantly lower input=output ratios than fields with ratings between 3.01 and 6.[15] The input=output ratio is a measure of the cost of producing a unit of output and is a better measure of land capability than output (yield) alone. This suggests that the LCC system provides an economically meaningful assessment of agricultural soil capability. Quantitative systems result in a numerical index, typically with the highest number being assigned to the land or soil with the highest capability for the selected use. The final index may be additive, multiplicative, or more complex functions of many land or soil attributes. Quantitative systems have two important advantages over nonquantitative systems: 1) they are easier to use with GIS and other automated data retrieval and display systems and 2) they typically provide a continuous scale of assessment.[16] No single national system is presently in use but several state or regional systems exist. One example of a quantitative system is the Storie index rating (SIR). Storie[17] determined that land productivity is dependent on 32 soil, climate, and vegetative properties. He combined only nine of these properties into the SIR, to keep the system from becoming unwieldy. The nine factors are soil morphology (A), surface texture (B), slope (C), and management factors drainage class (X1), sodicity (X2), acidity (X3), erosion (X4), micro-relief (X5), and fertility (X6). Each
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[6,16,20]
factor is rated from 1 to 100%. These are converted to their decimal value and multiplied together to yield a single rating for a soil map unit[17–19] [Eq. (1)]: SIR ¼
A B C
6 Y
! Xi
100
ð1Þ
i¼1
An area-weighted SIR can be calculated by multiplying the SIR for each soil map unit within a parcel by the area of the soil unit within the parcel, followed by summing the weighted values and dividing by the total area [Eq. (2)]. 1 total area n X SIR soili area soili :
Area-weighted SIR ¼
i¼1
ð2Þ Values for each factor were derived from Storie’s experience mapping and evaluating soils in California, and in soil productivity studies in cooperation with California Agricultural Experiment Station cost-efficiency projects relating to orchard crops, grapes and cotton. Soils that were deep, which had no restricting subsoil horizons, and held water well had the greatest potential for the widest range of crops. Reganold and Singer[15] found that area-weighted average SIR values between 60 and 100 for 744 fields in the San Joaquin Valley had lower but statistically insignificant input=output ratios than fields with indices 10: High nitrate leaching risk Despite its simplicity, the NLI is generally effective in identifying high-leaching scenarios from low-leaching scenarios[10] and has been widely adopted in the United States for nutrient management planning on farms.
FRAMEWORK FOR AN IMPROVED N LEACHING INDEX Although the current NLI allows for the assessment of NO3-N leaching potential, it also has significant limitations because of its oversimplification of complex processes.[11] The NLI does not actually estimate the leaching of NO3-N and therefore cannot be directly tied to an enforceable water-quality standard (e.g., 10 mg L1 NO3-N). The index also ignores important processes that affect N leaching, such as denitrification, which is especially significant in fine-textured soils.[4] van Es, czymmek, and ketterings.[10] concluded that despite this shortcoming, the NLI still effectively identifies soil and climate regions of high and low leaching potential.
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Nitrate Leaching Index
Another major limitation of the NLI is the lack of a connection with management practices, such as N application rates and timing, crop type, and crop rotations, which greatly influence NO3-N leaching. This concern has, in some cases, been addressed by providing specific management guidelines for fields with high NLI values, such as conservative N applications, optimum timing of applications, cover cropping, etc.[10] Shaffer and Delgado[11] proposed a framework for an improved NLI through a technologically based index that requires the integration of databases describing soil hydraulic properties, climate, off-site factors and management, the use of simulation models, and the internet. This NLI is proposed to use a dynamic ranking system similar to that for the P Index,[12] which can facilitate a preliminary assessment by classifying combinations of management scenarios, soil conditions, climate, crop types and off-site factors into leaching potential ratings. This NLI should be simple enough that it can be used by consultants, agronomists, conservationists, farmers, and technical personnel. It is proposed to have a tiered approach, where initial efforts involve simple screening to separate the higher NO3-N leaching potential scenarios from the lower ones.[11] Higher tiers of this NLI should be capable of assessing N leaching potential within the context of more complex N dynamics, transformations, and mobility in the root zone. Also, this NLI must be developed so it can be simultaneously used with the P Index to perform integrated analyses of nutrient loss potential, and allows for the evaluation of environmental tradeoffs associated with management practices. For example, early-fall manure application in the cool temperate regions of the United States is often optimal for avoiding P runoff losses, but poses high N leaching risk compared to other seasonal application periods.[10] At the first tier of application, the NLI should be simple enough to be applied across large regions. At the higher, more complex levels, the NLI should be capable of evaluating the leaching potential related to site-specific management scenarios by being coupled to GIS and capable of identifying variable NO3-N leaching areas across single fields of various soil characteristics and management scenarios. A final attribute of a new NLI should be its national scope and consistency, but not necessarily identical formulation. This allows for uniform standards and effective communication among technical service providers and scientists.[11] A new NLI needs to be developed with mechanistic dynamic simulation models (e.g., GPFARM, EPIC, LEACHM, NLEAP, GLEAMS, RZWQM) that can account for the complex N pathways, transformations, and interactions with other nutrients.[13] This is especially important for the evaluation of cases where organic N sources are being applied to the fields, which are generally of greatest concern with nutrient losses.
Nitrate Leaching Index
CONCLUSIONS The current NLI is a rapid assessment tool that evaluates the N leaching potential based on basic soil and climate information. It is the basis for many current nutrient management planning efforts, but has considerable limitations because of 1) an oversimplification of the processes affecting N leaching, and 2) a lack of management considerations. Improved N management in the landscape requires a new NLI that considers the complex interactions of climate conditions, soil characteristics, crop type, off-site factors, and management scenarios. A tiered approach is proposed to achieve these multiple objectives.[11] REFERENCES 1. Hallberg, G.R. Nitrate in ground water in the United States. In Nitrogen Management and Ground Water Protection; Follett, R.F., Ed.; Elsevier: New York, NY, 1989; 35–74. Chapter 3. 2. USEPA (United States Environmental Protection Agency). Federal Register: Washington, DC, May 1989; 2254 FR 22062. 3. Randall, G.W.; Huggins, D.R.; Russelle, M.P.; Fuchs, D.J.; Nelson, W.W.; Anderson, J.L. Nitrate losses through subsurface tile drainage in conservation reserve program, alfalfa and row crop systems. J. Environ. Qual. 1997, 26, 1240–1247. 4. Sogbedji, J.M.; van Es, H.M.; Yang, C.L.; Geohring, L.D.; Magdoff, F.R. Nitrate leaching and N budget as affected by maize N fertilizer rate and soil type. J. Environ. Qual. 2000, 29, 1813–1820.
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5. Williams, J.R.; Kissel, D.E. Water percolation: an indicator of nitrogen-leaching potential. In Managing Nitrogen for Groundwater Quality and Farm Profitability; Follet, R.F., Ed.; Soil Science Society of America Inc.: Madison, WI, 1991; 59–83. 6. Delgado, J.A. Quantifying the loss mechanisms of nitrogen. J. Soil Water Conserv. 2002, 57, 389–398. 7. Moisier, A.R.; Doran, J.W.; Freney, J.R. Managing soil denitrification. J. Soil Water Conserv. 2002, 57, 505–513. 8. Meisinger, J.J.; Delgado, J.A. Principles for managing nitrogen leaching. J. Soil Water Conserv. 2002, 57, 485–498. 9. Pierce, F.J.; Shaffer, M.J.; Halvorson, A.D. Screening procedure for estimating potentially leachable nitrate– nitrogen below the root zone. In Managing Nitrogen for Groundwater Quality and Farm Profitability; Follet, R.F., Ed.; Soil Science Society of America, Inc.: Madison, WI, 1991; 259–283. 10. van Es, H.M.; Czymmek, K.J.; Ketterings, Q.M. Management effects on N leaching and guidelines for an N leaching index in New York. J. Soil Water Conserv. 2002, 57, 499–504. 11. Shaffer, M.J.; Delgado, J.A. Essentials of a national nitrate leaching index assessment tool. J. Soil Water Conserv. 2002, 57, 327–335. 12. Sharpley, A.N.; Daniel, T.; Sims, T.; Lemunyon, J.; Stevens, R.; Parry, R. Agricultural Phosphorus and Eutrophication; USDA-ARS, 1999; ARS-149. 37 pp. 13. Delgado, J.A. Use of simulations for evaluation of best management practices on irrigated cropping systems. In Modeling Carbon and Nitrogen Dynamics for Soil Management; Shaffer, M.J., Ma, L., Hansen, S., Eds.; Lewis Publishers: Boca Raton, Florida, 2001; 355–381.
Nitrate Leaching Management John J. Meisinger United States Department of Agriculture (USDA), Beltsville, Maryland, U.S.A.
Jorge A. Delgado United States Department of Agriculture (USDA), Fort Collins, Colorado, U.S.A.
Ashok Alva United States Department of Agriculture (USDA), Prosser, Washington, U.S.A.
INTRODUCTION Nitrate leaching occurs when the soil nitrate–nitrogen (NO3–N) concentrations are high and water moves beyond the root zone. Leaching losses in modern agriculture commonly account for 10–30% of the nitrogen (N) additions.[1–3] Leaching can contribute to nitrate enrichment of groundwater, which has a health advisory limit of 10 mg NO3–N=L, and to eutrophication of surface waters that can lead to the development of hypoxic zones in receiving waters. Managing leaching requires development of site-specific practices that should be based on an: understanding of the soil–crophydrologic cycle, avoiding excess N by applying a N rate to meet expected yields, and applying N in phase with crop demand. Specific nitrate management approaches include adjusting irrigation inputs according to site water needs, employing cropping systems that fully utilize soil-water resources, and utilizing within-season and real-time N monitoring tools. The goal of this entry is to discuss practical techniques to reduce nitrate leaching from modern agriculture.
APPROACHES FOR DECREASING NITRATE LEACHING Primary Techniques for Managing Nitrate Leaching The major nitrate leaching management techniques include understanding the soil–crop-hydrologic cycle, applying the proper rate of N, and applying N in phase with crop demand. Because water movement is the driving force for nitrate leaching, it is essential to understand the hydrologic cycle before developing site-specific leaching management strategies.[1] Understanding the hydrologic cycle of the site should identify the most likely times when leaching can occur, i.e., the times when the soil is at near field capacity and water inputs exceed water use by evapotransporation (ET). 1122 Copyright © 2006 by Taylor & Francis
In humid regions, leaching is usually minimal in summer when ET exceeds precipitation. But during the winter-to-spring season, precipitation exceeds ET and leaching is common, as shown by the percolate data of Fig. 1, adapted from large monolith lysimeter data from Ohio, U.S.A.[3] In irrigated agriculture leaching is most likely to occur during the growing season from excess water inputs on coarse-textured soils. Controlling leaching in humid regions should focus on management practices to keep the soil NO3-N levels low during the fall season and on providing a crop N sink during the nongrowing season, such as a grass cover crop. In irrigated agriculture, avoiding excess irrigation inputs through irrigation scheduling is an effective method to manage leaching. Avoiding excess N inputs, from fertilizer and=or manure, is the most fundamental approach to control leaching because crop N use efficiency is usually high for plants responding to N. By contrast, N rates on the nonresponsive part of the yield curve are associated with lower efficiencies and high levels of unused N that is vulnerable to leaching. The data of wheat grain N removals (assuming 20 kg N=t grain) from the Rothemstad Broadbalk Study is summarized in Fig. 2; the associated estimate of N leaching is adapted from Gouldings.[4] These data show only small leaching losses for N rates in the responsive part of the curve, with a marked increase in leaching in the nonresponsive portion of the curve (Fig. 2). Applying the proper N rate usually involves estimating the crop N need from the expected yield and then subtracting N credits from residual NO3-N, irrigation N inputs, prior legume crop credits, and adjusting for available manure N.[1] Applying N in phase with crop demand is also a fundamental approach for managing leaching that involves applying N after crop establishment, or after each forage harvest in grass-forage systems. Timing N applications to closely match crop N uptake minimizes the time that N is exposed to uncontrolled rainfall inputs and thus leads to lower leaching losses. Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120026541 Copyright # 2006 by Taylor & Francis. All rights reserved.
Nitrate Leaching Management
Fig. 1 Monthly lysimeter percolate (upper panel) and N leached (lower panel, as percent of total yearly N leached) for large monolith lysimeters in Coshocton, Ohio, U.S.A. (From Ref.[3].)
Irrigation and Cropping System Techniques for Managing Nitrate Leaching Other nitrate management techniques include irrigation scheduling, modifying the cropping system, and developing riparian zones and conservation acres. Irrigation water management techniques are based on irrigation scheduling, which adds irrigation in accordance with ET and soil water status. Irrigation scheduling can reduce leaching by avoiding excess water applications, by adjusting water inputs to local weather, and by adding water based on local soil properties and local soil water content. For example, irrigating at 85% of ET, compared to 100% of ET, reduced leaching losses from about 110 to 60 kg N=ha on a sandy soil in Nebraska, U.S.A.[5] Similarly,
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Diez et al.[6] reported that scheduled irrigations to account for crop water demands can reduce the leaching of water and of NO3-N by four times, compared to excess irrigation. Meisinger and Delgado[1] summarized cropping system effects on leaching and concluded that adding a grain legume, such as soybeans, can partially reduce leaching compared to continuous corn (typically 5–10%), but adding a forage crop such as alfalfa or a forage grass, can substantially reduce leaching (typically 70–90%). However, changing the cropping system requires simultaneous changes in marketing and=or livestock enterprises. Delgado[7] reported that cropping systems that have shallowrooted crops and are heavily fertilized are most susceptible to NO3-N leaching. However, N recovery can be significantly improved by adding a deep-rooted crop such as malting barley. The barley served as a scavenger crop and even mined NO3-N from the system.[7] Adding a grass cover crop is another cropping system approach to reduce leaching by converting mobile NO3-N to immobile plant protein. A review of the effects of cover crops on water quality[8] concluded that grass covers can reduce nitrate leaching by an average of 70% compared to no-cover, while legume covers can reduce leaching by about 20%. Cover crops are especially useful in humid regions, where the winter leaching potential is high (Fig. 1). Developing riparian zones and conservation reserve areas can reduce the N loss from production fields into adjacent streams, especially in tile-drained watersheds.[1]
Other Approaches for Managing Nitrate Leaching Meisinger and Delgado[1] have also discussed other leaching management techniques. Nitrification inhibitors can delay leaching losses but are most effective in conjunction with other techniques, such as reduced N rates. Changing tillage practices usually have only secondary effects on leaching. Drainage-ditch water control measures can reduce nitrate transport to streams by impounding water and promoting denitrification, but have limited geographic applicability. Improved N application equipment is a direct approach to improve N application accuracy and avoiding excess N rates; new application equipment can apply N at the meter and submeter spatial scale.
Within-Season Monitoring Techniques for Managing Nitrate Leaching Fig. 2 Wheat grain N yield and N leaching for various fertilizer rates; Broadbalk Study, Rothamsted, U.K. (From Ref.[4].)
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In-season testing and real-time sensors are recently developed tools for managing leaching. These monitoring approaches seek to identify N sufficient or deficient
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areas within a field and adjust subsequent N applications accordingly. The leaf chlorophyll meter (LCM) compares leaf greenness to the LCM reading in a well-fertilized reference strip. The relative LCM value has been shown to successfully predict the need for extra fertilizer N, especially in irrigated systems where N can be applied with irrigation water.[9] The presidedress soil nitrate test (PSNT) measures NO3-N in the surface 30 cm of soil when corn is about 30 cm tall, and compares it to a sufficiency concentration of 20–25 mg NO3-N=kg. The PSNT is most useful for diagnosing N sufficient sites. A Connecticut, U.S.A., study[10] compared conventional N management with the PSNT and reported N leaching loses of 50 and 20 kg N=ha, respectively. Plant stem or petiole NO3-N tests measure plant NO3-N sufficiency at specific growth stages and are commonly used in vegetable crops.[1] Real-time sensors that measure crop biomass and greenness based on remotely sensed or tractormounted units, sense red and near infra-red reflectance,[1] and are new tools for managing N leaching. Data from real-time sensors have a meter to submeter resolution and can be combined with geographically mapped data of soil properties and previous crop yields to produce a real-time assessment of N status, potential yield, and the suggested N application based on crop simulation models such as nitrate leaching and economic analysis package (NLEAP).[7] These above seasonal and real-time monitors have been shown to reduce nitrate leaching by identifying N sufficient areas and avoiding applications of excess N; they can also increase profitability by identifying N deficient areas with excellent small-scale resolution. An example of the benefits from Precision Agriculture has been reported by Bausch and Delgado[11] who reported that using GIS and remote sensing tools for in-season N management resulted in N applications that required 52% less N than that used under conventional practices (214 kg N=ha=yr). On average, the in-season N management saved 102 kg N=ha=yr which was worth about $55=ha=yr, without yield reductions during two consecutive growing seasons. These results show that precision management can significantly improve N efficiency of corn systems without reducing grain yields, thus minimizing the potential for NO3-N leaching.
CONCLUSIONS Nitrate leaching is a significant N loss process for agriculture that must be managed to minimize nitrate enrichment of groundwater and surface waters. Managing nitrate leaching should involve application of the basic principles of understanding the site’s hydrologic cycle, avoiding excess rates of N, and applying N in phase with crop demand. Other specific techniques to
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Nitrate Leaching Management
reduce leaching include use of irrigation scheduling, grass cover crops, within-season monitoring with soil NO3-N tests or leaf chlorophyll meters, real-time sensors using red and near infra-red reflectance, and use of remote sensing with geographic information systems and simulation models to identify the best combination of practices to control leaching. Application of a specific combination of the above practices should increase crop N recovery with concomitant reductions in NO3-N leaching.
REFERENCES 1. Meisinger, J.J.; Delgado, J.A. Principles for managing nitrogen leaching. J. Soil Water Conserv. 2002, 57 (6), 485–498. 2. Legg, J.O.; Meisinger, J.J. Soil nitrogen budgets. In Nitrogen in Agricultural Soils; Stevenson, F.J., Bremner, J.M., Hauck, R.D., Keeney, D.R., Eds.; American Society of Agronomy: Madison, WI, 1982; Monograph No. 22, 503–566. 3. Chichester, F.W.; Smith, S.J. Disposition of 15N-labeled fertilizer nitrate applied during corn culture in field lysimeters. J. Environ. Quality 1978, 7 (2), 227–233. 4. Gouldings, K. Nitrate leaching from arable and horticultural land. Soil Use Manage. 2000, 16 (1), 145–151. 5. Hergert, G.W. Nitrate leaching through sandy soil as affected by sprinkler irrigation management. J. Environ. Quality 1986, 15 (3), 272–278. 6. Diez, J.A.; Roman, R.; Caballero, R.; Caballero, A. Nitrate leaching from soils under a maize-wheat-maize sequence, two irrigation schedules and three types of fertilizers. Agric. Ecosyst. Environ. 1997, 65 (1), 189–199. 7. Delgado, J.A. Use of simulations for evaluation of best management practices on irrigated cropping systems. In Modeling Carbon and Nitrogen Dynamics for Soil Management; Shaffer, M.J., Ma, L., Hansen, S., Eds.; Lewis Publishers: Boca Raton, FL, 2001; 355–381. 8. Meisinger, J.J.; Hargrove, W.L.; Mikkelsen, R.B.; Williams, J.R.; Benson, V.W. Effect of cover crops on groundwater quality. In Cover Crops for Clean Water; Hargrove, W.L., Ed.; Soil and Water Conservation Society of America: Ankeny, IA, 1991; 57–68. 9. Blackmer, T.M.; Schepers, J.S. Use of a chlorophyll meter to monitor nitrogen status and schedule fertigation for corn. J. Production Agric. 1995, 8 (1), 56–60. 10. Guillard, K.; Morris, T.F.; Kopp, K.L. The pre-sidedress soil nitrate test and nitrate leaching from corn. J. Environ. Quality 1999, 28 (6), 1845–1852. 11. Bausch, W.C.; Delgado, J.A. Ground base sensing of plant nitrogen status in irrigated corn to improve nitrogen management. In Digital Imaging and Spectral Techniques: Applications to Precision Agriculture and Crop Physiology ; Van Toai, T., Major, D., McDonald, M., Schepers, J., Tarpley, L., Eds.; Am. Soc. Agronomy Spec. Pub. 66: Madison, WI, 2003; 151–163.
Nitrogen and Its Transformations Oswald Van Cleemput Pascal Boeckx Ghent University, Ghent, Belgium
INTRODUCTION Nitrogen (N) is essential to all life. It is the nutrient that most often limits biological activity. In agricultural and natural ecosystems, N occurs in many forms covering a range of valence states from 3 to þ5. The change from one valence state to another depends primarily on environmental conditions. The transformations and flow from one form to another constitute the basics of the soil N cycle (Fig. 1). The use of N fertilizers has become essential to increase the productivity of agriculture, and has resulted in an almost doubling of the global food production in the past 50 years. However, this also implies that the natural N cycle has substantially been disturbed. In the following paragraphs an overview of the different N transformation processes in the soil is given.
THE NITROGEN CYCLE: GENERAL Atmospheric N2 gas (valence 0) can be converted by lightening to various oxides and finally to nitrate (NO3) (valence þ5), which can be deposited and taken up by growing plants. Also N2 gas can be converted to ammonia (NH3, valence 3) by biological N2 fixation, with the NH3 participating in a number of biochemical reactions in the plant. When plant residues decompose the N-compounds undergo a series of microbial conversions (mineralisation) leading first to the formation of ammonium (NH4þ) (valence 3) and possibly ending up in NO3 (nitrification). Under anaerobic conditions NO3 can be converted to various N-oxides and finally to N2 gas (denitrification). When mineral or organic N fertilizers are used they also undergo the same transformation processes and influence the rate of other Ntransformations. In considering the soil compartment, there can be N gains (such as biological N2 fixation) as well as N losses (such as leaching and denitrification). Furthermore N can be exported from the soil via harvest products, or immobilized in soil organic matter.
NITROGEN TRANSFORMATIONS IN THE SOIL The principal forms of N in the soil are NH4þ, NO3 or organic N-substances. At any moment, inorganic Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001574 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
N in the soil is only a small fraction of the total soil N. Most of the N in a surface soil is present as organic N. It consists of proteins (20–40%), amino sugars, such as the hexosamines (5–10%), purine and pyrimidime derivates (1% or less), and complex unidentified compounds formed by reaction of NH4þ with lignin, polymerization of quinones with N compounds and condensation of sugars and amines. In the subsoil, an important fraction of the present N can be trapped in clay lattices (especially illitic clays) as nonexchangeable NH4þ and is consequently largely unavailable. Organic substances slowly mineralize by microorganisms to NH4þ, which could be converted by other microorganisms to NO3 (see further). The NH4þ can be adsorbed to negatively charged sites of clay minerals and organic compounds. This reduces its mobility in the soil compared to the more mobile NO3 ion. Microorganisms can use both NH4þ and NO3 to satisfy their need for N. This type of N transformation is called microbial immobilization. The ratio between carbon (C) and N (C : N ratio) in organic matter determines whether immobilization or mineralization is likely to occur. When utilizing organic matter with a low N content, the microorganisms need additional N, decreasing the mineral N pool of the soil. Thus, incorporation of organic matter with a high C : N ratio (e.g., cereal straw) results in immobilization. Incorporation of organic matter with a low C : N ratio (e.g., vegetable or legume residues) results in N-mineralization. A value of the C : N ratio of 25 to 30 is often taken as the critical point toward either immobilization or mineralization. Nitrification is a two-step process. In the first step NH4þ is converted to nitrite (NO2) (valence þ3) by a group of obligate autotrophic bacteria known as Nitrosomonas species. The second step is carried out by another group of obligate autotrophic bacteria known as Nitrobacter species. Also a few heterotrophs can carry out nitrification, usually at much lower rates. Soil water and aeration are crucial factors for nitrification. At a water potential of 0 kPa (saturation), there is little air in the soil and nitrification stops, due to oxygen limitation; nitrification is greatest near field capacity (33 kPa in medium- to heavy-textured soils, to 0 to 10 kPa in light sandy soils). Also in 1125
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Fig. 1 The soil N cycle. The white compartment represents the atmosphere; the light gray compartment represents the biosphere and the dark gray compartment the subsoil.
dry soils NH4þ and sometimes NO2 accumulate presumably because Nitrobacter species are more sensitive to water stress than the other microorganisms. Nitrification is slow in acid conditions with an increasing rate at increasing pH. Mainly under alkaline conditions, nitrite is also accumulating, because Nitrobacter is known to be inhibited by ammonia, which is formed under alkaline conditions. Nitrification is a process that acidifies the soil as protons (Hþ) are liberated: NH4þ þ 2O2 ! NO3 þ 2Hþ þ H2 O During nitrification minor amounts of nitrous oxide (N2O) (valence þ1) and nitric oxide (NO) (valence þ2) are formed. Both compounds have environmental consequences, discussed below. The effect of temperature on nitrification is climate dependent. There is a climatic selection of species of nitrifiers, with those from cooler regions having lower temperature optima and less heat tolerance than species from warmer regions. All above-mentioned factors influencing nitrification also influence the nitrifying population. The population and activity of nitrifiers can be reduced by the use of nitrification inhibitors, such as dicyanodiamide, nitrapirin and neem (Azadirachta indica) seed cake. They are used mostly to retard
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the nitrification of manure; otherwise their practicality is controversial and they are not extensively used. More details about nitrification and nitrification inhibitors can be found in McCarty[1] and Prosser.[2] NITROGEN INPUT PROCESSES Atmospheric Nitrogen Deposition The total atmospheric N (NH4þ and NO3) deposition is in the order of 10–40 kg N ha1 yr1 in much of north-western and central Europe and some regions in North America. It ranges from 3–5 kg N ha1 yr1 in pristine areas.[3] It is originating from previously emitted NH3 and NOx from agricultural and industrial activities or traffic. Biological Nitrogen Fixation Rhizobium species living in symbiotic relationship in root nodules of legumes, e.g. clover (Trifolium), lucerne (Medicago), peas (Pisum) and beans (Faba)— can convert atmospheric N2 gas to NH3, which is further converted to amino acids and proteins. Parallel to this process, the rhizobium species receive from the legume the energy they need to grow and to fix N2.
Nitrogen and Its Transformations
Photosynthetic cyanobacteria are also N-fixing organisms and are especially important in paddy rice (Oryza). The amount of N fixed varies greatly from crop to crop, ranging from a few kg to a few hundred kg N ha1 yr1. The process is depressed by ample N supply from other sources, and it is sensitive to lack of phosphorus. The amount of globally fixed N is almost the double the amount of applied fertilizer N. Next to symbiotic N fixing bacteria also non-symbiotic species (e.g. Azotobacter) occur in soils. In general, free-living diazotrophs make a small but significant contribution to the soil N status. Some nonleguminous trees and plants (e.g. alder (Alnus), sugarcane (Saccharum) host N-fixing bacteria as well. Much uncertainty exists about the association of N fixing bacteria with non-legumes (so called associative N fixing bacteria). Mineral and Organic Nitrogen Fertilization Theoretically plants should prefer NH4þ above NO3, because NH4þ does not need to be reduced before incorporation into the plant. In most well-drained soils oxidation of NH4þ is fairly rapid and therefore most plants have developed to grow better with NO3. However, a number of studies have shown that plants better develop when both sources are available. Rice, growing under submerged conditions must grow in the presence of NH4þ as NO3 is not stable under flooded conditions. When urea is applied it rapidly hydrolyzes under well-drained conditions, unless a urease inhibitor is being added; under submerged conditions rice plants may also absorb N directly as molecular urea. Organic manure can be of plant or animal origin or a mixture of both. However, most comes from dung and urine from farm animals. It exists as farmyard or stable manure, urine, slurry or as compost. Because its composition is not constant and because plant material (catch or cover crops, legumes) is often added freshly (green manure) to the soil, less than 30% of its nutrients becomes available for the next crop.
NITROGEN UPTAKE BY PLANTS Growing plants get their N from fertilizer N as well as from organic soil N upon mineralization. Plants take up N compounds both as NO3 and as NH4þ. In general, NO3 is the major source of plant N. There is some evidence that small amounts of organic N (urea or amino acids) can be taken up by plants from the soils solution. Plant uptake of N can be studied through the use of mineral fertilizers or organic matter labeled with the stable N isotope 15N. The proportion of applied N taken up by the crop is affected by
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many factors, including crop species, climate and soil conditions. Above ground parts of the crop can recover 40–60% of the fertilizer N applied.
NITROGEN LOSS PROCESSES Ammonia Volatilization Losses of N from the soil by NH3 volatilization amount globally to 54 Mt (or 1012 g) NH3-N yr1 and 75% is of anthropogenic origin.[4] According to the ECETOC,[5] the dominant source is animal manure and about 30% of N in urine and dung is lost as NH3. The other major source is surface application of urea or ammonium bicarbonate and to a lesser degree other ammonium-containing fertilizers. As urea is the most important N fertilizer in the world, it may lead to important NH3 loss upon hydrolysis and subsequent pH rise in the vicinity of the urea till. The transformation of NH4þ to the volatile form NH3 increases with increasing pH, temperature, soil porosity, and wind speed at the soil surface. It decreases with increasing water content and rainfall events following application. Ammonia losses from soils can be effectively reduced by fertilizer incorporation or injection instead of surface application. Emission of Nitrogen Oxides (N2O, NO) and Molecular Nitrogen (Nitrification and Denitrification) Microbial nitrification and denitrification are responsible for the emission of NO and N2O.[6] They are by-products in nitrification and intermediates during denitrification. Probably about 0.5% of fertilizer N applied is emitted as NO[7] and 1.25% as N2O.[8] However, wide ranges have been reported. Intensification of arable agriculture and of animal husbandry has made more N available in the soil N cycle increasing the emission of N oxides. The relative percentage of NO and N2O formation very much depends on the moisture content of the soil. At a water-filled pore space (WFPS, or the fraction of total soil pore space filled with water) below 40% NO is produced mainly from nitrification. Between a WFPS of 40% and 60% formation of NO and N2O from nitrification occurs. Between a WFPS of 60% and 80% N2O is predominantly produced from denitrification and the formation of NO is decreasing sharply. At a WFPS above 80% the formation of N2 by denitrification is dominant. In practice these WFPS ranges will overlap anddepend on the soil type.[9] Next to water content, also temperature, land use and availability of N and decomposable organic matter are important determining factors for N2O formation. Nitrous oxide is a greenhouse
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gas contributing 5–6% to the enhanced greenhouse effect. Increased concentrations are also detrimental for the stratospheric ozone layer.[10] In the presence of sunlight, NOx (NO and NO2) react with volatile organic compounds from evaporated petrol and solvents and from vegetation and forms tropospheric ozone which is, even at low concentration, harmful to plants and human beings. The major gaseous end-product of denitrification is N2. The ratio of N2O to N2 produced by denitrification depends on many environmental conditions. Generally themore anaerobic the environment the greater the N2 production. Denitrification is controlled by three primary factors (oxygen, nitrate and carbon), which in turn are controlled by several physical and biological factors. Denitrification N loss can reach 10% of the fertilizer N input—more on grassland and when manure is also applied.[11] Chemical denitrification is normally insignificant and is mainly related to the stability of NO2 and acid conditions.[12] It is more difficult to reduce N2O and NO from soils then NH3 losses. A general principle is to minimize N surpluses in the soil profile via carefulfertilizer adjustment, corresponding to the actual crop demands. Leaching Applied NO3 or NO3, formed through nitrification from mineralized NH4þ or from NH4þ from animal manure, can leach out of the rooting zone. It is well possible that this leached NO3 can be denitrified at other places and returned into the atmosphere. The amount and intensity of rainfall, quantity and frequency of irrigation, evaporation rate, temperature, soil texture and structure, type of land use, cropping and tillage practices and the amount and form of fertilizer N are all parameters influencing the amount of NO3 leaching to the underground water. Nitrate leaching should be kept under control as it may influence the nitrate content in drinking water influencing human health and in surface water, causing eutrophication. Nitrate losses can be minimized by reducing the mineral N content in the soil profile during the
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Nitrogen and Its Transformations
winter period by careful fertilizer adjustment, growing of cover crops or riparian buffer areas.
REFERENCES 1. McCarty, G.W. Modes of action of nitrification inhibitors. Biol. Fert. Soils 1999, 29, 1–9. 2. Prosser, J.I., Ed. Nitrification, Special Publications of the Society of General Microbiology; IRL Press: Oxford, 1986; 20 pp. 3. Lagreid, M.; Bockman, O.C.; Kaarstad, O. Agriculture, Fertilizers and the Environment; CIBA Publishing: Oxon, UK, 1999; 294 pp. 4. Sutton, M.A.; Lee, D.S.; Dollard, G.J.; Fowler, D. International conference on atmospheric ammonia: emission, deposition and environmental impacts. Atmospheric Environment 1998, 32, 1–593. 5. ECETOC Ammonia Emissions to Air in Western Europe, (No. 62); European Centre for Ecotoxicology and Toxicology of Chemicals: Brussels, 1994; 196 pp. 6. Bremner, J.M. Sources of nitrous oxide in soils. Nutr. Cycl. Agroecosys. 1997, 49, 7–16. 7. Veldkamp, E.; Keller, M. Fertilizer-induced nitric oxide emissions from agricultural soils. Nutr. Cycl. Agroecosys. 1997, 48, 69–77. 8. Mosier, A.; Kroeze, C.; Nevison, C.; Oenema, O.; Seitsinger, S.; Van Cleemput, O. Closing the global N2O budget: nitrous oxide emissions through the agricultural N cycle. Nutr. Cycl. Agroecosys. 1998, 52, 225–248. 9. Davidson, E.A. Fluxes of Nitrous Oxide and Nitric Oxide from terrestrial ecosystems. In Microbial Production and Consumption of Greenhouse Gases: Methane, Nitrogen Oxides, and Halomethanes; Rogers, J.E., Whitman, W.B., Eds.; American Society for Microbiology: Washington, DC, 1991; 219–235. 10. Crutzen, P.J. The influence of nitrogen oxides on the atmospheric ozone content. Quat. J. Royal Meteor. Soc. 1976, 96, 320–325. 11. von Rheinbaben, W. Nitrogen losses from agricultural soils through denitrification—A critical evaluation. Z. Pflanzenern. Bodenk. 1990, 153, 157–166. 12. Van Cleemput, O. Subsoils: chemo- and biological denitrification, N2O and N2 emissions. Nutr. Cycl. Agroecosys. 1998, 52, 187–194.
Nitrous Oxide Emissions: Agricultural Soils John R. Freney Commonwealth Scientific and Industrial Research Organisation (CSIRO) Plant Industry, Canberra, Australian Capital Territory, Australia
INTRODUCTION Nitrous oxide is a gas that is produced naturally by many different micro-organisms in soils and waters, and as a result of human activity associated with agriculture, biomass burning, stationary combustion, automobiles, and the production of nitric and adipic acids for industrial purposes. According to the Intergovernmental Panel on Climate Change (IPCC),[1] 23.1 million metric tons (Mt) of nitrous oxide is emitted each year, 14.1 Mt as a result of natural processes (4.7 Mt from the oceans, 6.3 Mt from tropical soils, and 3.1 Mt from temperate soils); and 9 Mt as a result of human activities (5.5 Mt from agricultural soils, 0.6 Mt from cattle and feedlots, 0.8 Mt from biomass burning, and 2.1 Mt from mobile sources and industry). While there is considerable uncertainty associated with each of these estimates, it is apparent that most nitrous oxide is derived from soils. Because of the intimate connection between the Earth and the atmosphere, much of the nitrous oxide produced enters the atmosphere and affects its chemical and physical properties. Nitrous oxide contributes to the destruction of the stratospheric ozone layer that protects the Earth from harmful ultraviolet radiation, and is one of the more potent greenhouse gases that trap part of the thermal radiation from the Earth’s surface. The atmospheric concentration of nitrous oxide is 313 parts per billion. It is increasing at the rate of 0.7 parts per billion each year, and its lifetime is 166 years.[2] It seems that the increased atmospheric concentration results from the increased use of synthetic fertilizer nitrogen, biologically fixed nitrogen, animal manure, crop residues, and human sewage sludge in agriculture to produce food and fiber for the rapidly increasing world population.[3]
NITROUS OXIDE EMISSION FROM AGRICULTURE All soils are deficient in nitrogen for the growth of plants, but the deficiency can be overcome by adding fertilizer nitrogen. When the fertilizer (e.g., urea or Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001564 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
ammonia-based compounds) is applied to soil, it is transformed by micro-organisms as follows: 1
2
Fertilizer nitrogen ! Ammonium ! Nitrite 3
4
! Nitrate ! Nitrite 5
6
! Nitric oxide ! Nitrous oxide 7
! Dinitrogen
ð1Þ
When the soil is aerobic (i.e., when oxygen is present) ammonium is oxidized to nitrite and nitrate (Steps 2 & 3). This process is called nitrification. After addition of irrigation water or rain, the soil may become anaerobic (devoid of oxygen). The nitrate is then reduced by soil organisms to nitrite and the gases nitric oxide, nitrous oxide, and dinitrogen (Steps 4–7) in a process termed denitrification.[4] When atmospheric scientists first expressed concern that nitrous oxide emission into the atmosphere, as a result of fertilizer use, would lead to destruction of the ozone layer, it was thought that nitrous oxide was produced mainly from the microbiological reduction of nitrate in poorly aerated soils. However, research in the latter part of the 1970s showed that significant nitrous oxide was emitted from aerobic soils during nitrification of ammonium, and subsequent work has shown that nitrification is a major source of nitrous oxide.[4]
Nitrous Oxide from Denitrification Certain micro-organisms in the absence of oxygen have the capacity to reduce nitrate (or other nitrogen oxides). Most denitrifying bacteria are heterotrophs—that is, they require a source of organic matter for energy— but denitrifying organisms that obtain their energy from light or inorganic compounds also occur in soils. The capacity to denitrify has been reported in more than 20 genera of bacteria, and almost all are aerobic organisms that can only grow anaerobically in the presence of nitrogen oxides. The dominant denitrifying organisms in soil are Pseudomonas and Alcaligenes. In addition to the free-living denitrifiers, Rhizobia 1129
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living symbiotically in root nodules of legumes are able to denitrify nitrate and produce nitrous oxide.[4] The general requirements for biological denitrification include the presence of micro-organisms with denitrifying capacity, nitrate (or other nitrogen oxides) and available organic matter, the absence of oxygen, and a suitable pH and temperature environment. In aerobic soils, denitrification can occur in anaerobic microsites in soil aggregates or in areas of high carbon content, where active microbial activity rapidly consumes all of the available oxygen.[4] Nitrous Oxide from Nitrification The process of nitrification is normally defined as the biological oxidation of ammonium to nitrate with nitrite as an intermediate.[4] The first step in the reaction, the oxidation of ammonium to nitrite, is carried out mainly by the micro-organism Nitrosomonas. The second step, oxidation of nitrite to nitrate, is carried out by Nitrobacter. It has been shown in a number of publications that Nitrosomonas europaea produces nitrous oxide during the oxidation of ammonium.[4] The possibility that significant nitrous oxide can be produced in soils by nitrifying organisms was indicated by studies that showed that soils incubated under aerobic conditions with ammonium produced more nitrous oxide than soils amended with nitrate.[4] In addition, treatment of aerobic soils with nitrapyrin, which inhibits nitrification of ammonium but has little effect on denitrification, markedly reduced the emission of nitrous oxide.[4] Production of nitrous oxide by nitrification in soils is increased by increasing temperature, pH, water content, available carbon, and the addition of ammonium-based fertilizers, plant residues, and animal manure. Flooded Soils In the past few years, increased attention has been given to nitrous oxide emission from paddy soils. The concern is that the introduction of management practices to reduce methane emissions from flooded soils may result in increased emissions of nitrous oxide. Flooded soils are characterized by an oxygenated water column overlying an oxidized layer at the soil– water interface, an aerobic zone around each root, and anaerobic conditions in the remainder of the soil. This differentiation of the flooded soil into oxidized and reduced zones has a marked effect on the transformation of nitrogen.[5] The resulting reactions are as follows: 1. Ammonium in the reduced zone diffuses to the oxidized zone;
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Nitrous Oxide Emissions: Agricultural Soils
2. Ammonium is oxidized to nitrate by nitrifying organisms; 3. The nitrate formed diffuses to the anaerobic zone; 4. Denitrification occurs with the production of nitrous oxide and dinitrogen; 5. The gaseous products diffuse through the soil and water layers to the atmosphere.[6] It is apparent that the rate of diffusion of ammonium to an oxidized layer and the rate of nitrification in the oxidized layer are factors controlling the production of nitrous oxide in flooded soils. The rate of diffusion of nitrous oxide through the soil and water layers will control its rate of emission to the atmosphere, or its further reduction to dinitrogen.[5] A number of mechanisms have been identified for the transfer of nitrous oxide from the soil to the atmosphere.[3] Nitrous oxide may diffuse from the zone of production through the saturated soil and water layer to the atmosphere. It may also enter the roots of the rice plant and move by diffusion through the plant to the atmosphere in the same way as methane. Bhadrachalam et al.[6] studied the importance of the two pathways in intermittently flooded rice in the field in India and found that nitrogen gas fluxes were 30% greater when transfer through the plants was included. In the tropics, rice is usually transplanted and fertilized some time after flooding. Because of the anaerobic conditions that develop before fertilization and the slow rate of diffusion of nitrous oxide in flooded soils, most of the nitrous oxide is reduced to dinitrogen and very little escapes to the atmosphere. Nitrous oxide emission from intermittently flooded rice was relatively large compared with that from permanently flooded rice, reflecting the different oxidation states of intermittently and continuously flooded soils.[6] Studies of nitrous oxide emission from rice fields from the time the soils were drained for harvest, through to flooding the soil in preparation for planting the next crop, showed that nitrous oxide was emitted continuously while the soil was not flooded. Overall, the rate of emission of nitrous oxide from floodedsoils was less than that from upland soils after application of nitrogen fertilizer.[3]
Biomass Burning During combustion the nitrogen in the fuel can be converted into gaseous forms such as ammonia, nitric oxide, nitrous oxide, dinitrogen, and hydrogen cyanide. It is estimated that biomass burning contributes between 0.3 and 1.6 Mt nitrous oxide per year globally to the atmosphere.[3] Most of the biomass burning
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(90%) takes place in the tropics as a result of forest clearing, savanna and sugar cane fires, and burning of agricultural wastes and firewood.[7] Biomass burning is not only an instantaneous source of nitrous oxide, but it results in a longer-term enhancement of the production of this gas. Measurements of nitrous oxide emissions from soils, before and after burning showed that significantly more nitrous oxide was exhaled after the burn through alteration of the chemical, biological, and physical processes in soil.[7]
Table 1 Calculated emission of nitrous oxide from agricultural activities Mt nitrous oxide per year Direct soil emissions Synthetic fertilizer Animal waste Biological nitrogen fixation Crop residue Cultivation of Histosols Total
1.4 (0.28–2.5) 0.9 (0.19–1.7) 0.16 (0.03–0.3) 0.6 (0.11–1.1) 0.16 (0.03–0.3) 3.3 (0.6–5.9)
Animal production Waste management systems
3.3 (0.9–4.9)
Indirect emissions
Fertilizer Consumption and Nitrous Oxide Production Nitrous oxide emissions from agricultural soils are generally greater and more variable than those from uncultivated land. Application of fertilizer nitrogen, animal manure, and sewage sludge usually results in enhanced emissions of nitrous oxide.[7] Generally, there is a large emission of nitrous oxide immediately after the application of fertilizer. After about 6 weeks, the emission rate falls and fluctuates around a low value. Mosier[8] concluded that interactions between the physical, chemical, and biological variables are complex, that nitrous oxide fluxes are variable in time and space, and that soil management, cropping systems, and variable rainfall appear to have a greater effect on nitrous oxide emission than the type of nitrogen fertilizer. Consequently, Mosier et al.[9] recommend the use of one factor only for calculating the emission of nitrous oxide from different fertilizer types: N2 O emitted ¼ 1:25% of N applied ðkg N=haÞ
ð2Þ
This equation is based on data from long-term experi-ments with a variety of mineral and organic fertilizers, and encompasses 90% of the direct contributions of nitrogen fertilizers to nitrous oxide emissions. Mosier et al.[3] developed a methodology to estimate agricultural emissions of nitrous oxide, taking into account all of the nitrogen inputs into crop production. They included direct emissions from agricultural soils as a result of synthetic fertilizer addition, animal wastes, increased biological nitrogen fixation, cultivation of mineral and organic soils through enhanced organic matter mineralization, and mineralization of crop residues returned to the field. Indirect nitrous oxide emissions resulting from deposition of ammonia and oxides of nitrogen, leaching of nitrate, and introduction of nitrogen into sewage systems were also included. They concluded that in 1989, 9.9 Mt of
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Atmospheric deposition Nitrogen leaching and runoff Human sewage Total Total
0.47 (0.09–0.9) 2.5 (0.2–12.1) 0.3 (0.06–4.1) 3.3 (0.35–17.1) 9.9 (1.9–27.9)
(Modified from Ref.[3].)
nitrous oxide was emitted into the atmosphere directly or indirectly, as a result of agriculture (Table 1). MANAGEMENT PRACTICES TO DECREASE NITROUS OXIDE EMISSION The low efficiency of fertilizer nitrogen in agricultural systems is primarily caused by the large losses of mineral nitrogen from those systems by gaseous loss: nitrous oxide emission is directly linked to the loss processes. It is axiomatic that any strategy that increases the efficiency of nitrogen fertilizer use will reduce emissions of nitrous oxide, and this has been directly demonstrated for a number of strategies.[3] The IPCC[1] reported that some combination of the following management practices, if adopted worldwide, would improve the efficiency of the use of synthetic fertilizer and manure nitrogen, and significantly reduce nitrous oxide emission into the atmosphere: 1. Match nitrogen supply with crop demand. 2. Tighten nitrogen flow cycles by returning animal wastes to the field and conserving residues instead of burning them. 3. Use controlled-release fertilizers, incorporate fertilizer to reduce volatilization, use urease and nitrification inhibitors, and match fertilizer type to precipitation. 4. Optimize tillage, irrigation, and drainage. The potential decrease in nitrous oxide emissions from synthetic fertilizer, as a result of the mitigation techniques, could amount to 20%.[1]
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REFERENCES 1. IPCC (Intergovernmental Panel on Climate Change). Climate Change 1995. Impacts, Adaptations and Mitigation of Climate Change: Scientific–Technical Analyses; Watson, R.T., Zinyowera, M.C., Moss, R.H., Eds.; Cambridge University Press: Cambridge, England, 1996; 1–878. 2. Hengeveld, H.; Edwards, P. 1998. An assessment of new research developments relevant to the science of climate change. Climate Change Newsletter 2000, 12, 1–52. 3. Mosier, A.; Kroeze, C.; Nevison, C.; Oenema, O.; Seitzinger, S.; van Cleemput, O. Closing the global N2O budget: nitrous oxide emissions through the agricultural nitrogen cycle. Nutri. Cycling Agroecosys. 1998, 52, 225–248. 4. Bremner, J.M. Sources of nitrous oxide in soils. Nutri. Cycling Agroecosys. 1997, 49, 7–16. 5. Patrick, W.H., Jr. Nitrogen transformation in submerged soils. In Nitrogen in Agricultural Soils; Stevenson, F.J.,
Copyright © 2006 by Taylor & Francis
6.
7.
8.
9.
Ed.; American Society of Agronomy: Madison, WI, 1982; 449–465. Bhadrachalam, A.; Chakravorti, S.P.; Banerjee, N.K.; Mohanty, S.K.; Mosier, A.R. Denitrification in intermittently flooded rice fields and N-gas transport through rice plants. Ecol. Bull. 1992, 42, 183–187. Granli, T.; Bøckman, O.C. Nitrous oxide from agriculture. Norwegian J. Agric. Sci. 1994, Supplement No. 12, 1–128. Mosier, A.R. Chamber and isotope techniques. In Exchange of Trace Gas between Terrestrial Ecosystems and the Atmosphere; Andreae, M.O., Schimel, D.S., Eds.; John Wiley & Sons: Chichester, England, 1989; 175–187. Mosier, A.R.; Duxbury, J.M.; Freney, J.R.; Heinemeyer, O.; Minami, K. Nitrous oxide emissions from agricultural fields: assessment, measurement and mitigation. Plant Soil 1995, 181, 95–108.
Nitrous Oxide Emissions: Sources, Sinks, and Strategies Katsu Minami National Institute for Agro-Environmental Sciences, Tsukuba, Japan
INTRODUCTION
Sinks for Nitrous Oxide
Although it has been known for more than 50 years that nitrous oxide (N2O) is a regular constituent of the atmosphere, it was not considered to be of any importance as an air constituent until the early 1970s. Atmospheric scientists hypothesized that N2O released to the atmosphere through denitrification of nitrates in soils and natural waters may trigger reactions in the stratosphere leading to partial destruction of ozone layer protecting the earth from biologically harmful ultraviolet radiation from the sun.[1] Nitrous oxide is also one of the natural components of Earth’s atmosphere and contributes to the natural greenhouse effect; therefore the increasing of N2O in the atmosphere may be contributing to global warming.[2] The atmospheric concentration of N2O has been increasing at an accelerated rate for several decades at a rate of 0.8 ppbv=yr, and the lifetime of N2O is 120 yr. It has been estimated that doubling the concentration of N2O in the atmosphere would result in a 10% decrease in the ozone layer which would increase the ultraviolet radiation reaching the earth by 20%,[3] eventually leading to an increase in the occurrence of skin cancer and other health problems. The global warming potential (GWP) of each molecule of N2O is about 210 times (20-year horizon) greater than each molecule of CO2. Nitrous oxide currently accounts for 6% of total GWP.[4]
The major atmospheric loss process for N2O is photochemical decomposition by sunlight (wavelengths 180–230 nm) in the stratosphere and is calculated to be 12.3 (range 9–16) Tg N=yr. Tropospheric sinks such as surface loss in aquatic and soil systems are considered to be small as compared to atmospheric sink.[5] However, the paucity of data does not enable us to estimate the importance of this sink on a global basis.
THE BUDGET OF ATMOSPHERIC NITROUS OXIDE
Sources of Nitrous Oxide There are many sources of nitrous oxide, both natural and anthropogenic, which cannot be easily quantified. Undoubtedly, the earth and oceans are significant N2O sources. Nitrous oxide fluxes from upwelling regions of the Indian and Pacific Oceans clearly suggest that oceans may be a larger source. The ocean flux estimate is 3 (range 1–5) Tg N=yr. Tropical forest soils are probably the single most important source of N2O emission to the atmosphere. The total N2O emission from tropical soils (forest, savannah) is estimated at 4 (range 2.7–5.7) Tg N=yr. The magnitude of N2O emissions from intensively fertilized tropical agricultural soils has not been quantified. Also, no attempt has been made to separate the tropical soil sources into natural and anthropogenic components.[5] The main anthropogenic sources are derived from agriculture and a number of industrial processes such as adipic acid and nitric acid production. New research suggests that N2O emissions from cropped, nitrogenfertilized agricultural systems are significant on a global scale as shown in Table 1.
Atmospheric Distribution of Nitrous Oxide As a result of biotic and anthropogenic activities, the concentration of N2O in the atmosphere is increasing at the rate of about 0.25%=yr. The concentration of N2O is about 0.75 ppbv higher in the northern hemisphere than in the southern hemisphere, suggesting the presence of greater source of N2O in the northern hemisphere than in the southern hemisphere. Ice core measurements show that the preindustrial value of N2O was relatively stable at about 285 ppbv for most of the past 2000 years, and started to increase around the year 1700 associated with anthropogenic activity.[4,5] Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042718 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
Agricultural Fields About 40% of N2O sources are anthropogenic and, among them, fertilized soils account for about 60%.[5] This figure could be an underestimate because tropical agricultural soil sources resulting from human activities have not been separated from natural tropical soil sources. Agricultural N2O emissions are considered to arise from fertilization of soils with mineral N and animal manures, N derived from biological N fixation, and from enhanced soil N mineralization. Nitrous oxide is 1133
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Nitrous Oxide Emissions: Sources, Sinks, and Strategies
Table 1 The amount of N2O emission from agriculture (Mt=yr) Mineral fertilizer N-fixation Soils after burning Animal wastes Biomass burning Forest conversion
1.5 0.5 0.1 1.5 0.2 0.4
(0.5–2.5) (0.25–0.75) (0.05–0.2) (0.5–2.5) (0.1–0.3) (0.1–1)
Total
4.2 (1.5–7.25)
oxygen concentrations. Because oxygen supply is moderated by soil moisture, the effect of soil water content on N transformation probably reflects its impact on oxygen diffusion in the normal soil moisture range. Nitrous oxide emissions from N-fertilizer applied agricultural fields have been detected by Bremner and Blackmer.[7]
Denitrification directly evolved during biomass burning, and produced in soil after burning, and enhanced emissions arise during the clearing of tropical forests for agricultural activities.[4] Bouwman[6] estimated the total emissions of N2O from a regression equation: total annual direct field N2O–N Loss ¼ 1 þ 0.0125 N-application (Kg N=ha). The value of 1 Kg N2O–N=ha represents the background N2O-N evolved and the 0.0125 factor expresses for the contribution from fertilization. This estimate includes N sources from a variety of mineral and organic N fertilizers and was based on long-term data sets. About 40% of the estimated N2O production is derived from North and Central America, Europe, and the former Soviet Union where about 20% of the world human population resides. Asian countries that hold about 55% of the global human population contribute about 40% of the estimated annual N2O production.[4]
MECHANISM OF NITROUS OXIDE PRODUCTION
Biological denitrification refers to the dissimilatory reduction of nitrate and nitrite to produce NO, N2O, and N2 by a taxonomically diverse group of bacteria which synthesize a series of reductases that enable them to utilize successively more reduced N oxides as electron acceptors in the absence of oxygen. The general reductive sequence is as follows NO3 ! NO2 ! NO ! N2 O ! N2 The most abundant denitrifiers are heterotrophs that require sources of electron-reducing equivalents contained in available organic matter. Soil factors that most strongly influence denitrification are oxygen, nitrate concentration, pH, temperature, and organic carbon. Nitrous oxide reductase appears to be more sensitive to oxygen than either nitrate or nitrite reductase. Therefore, N2 production predominates in more anoxic sites and N2O production may be higher under more aerobic conditions.
Chemical Decomposition of Nitrite (Chemodenitrification)
Nitrification Nitrification is the reaction whereby ammonium is oxidized to nitrate. In soils, autotrophic and heterotrophic bacteria mediate this process. The most common ammonium oxidizers are Nitrosomonas spp., which are involved in the formation of nitrite, while nitrite oxidation to nitrate is usually achieved by Nitrobacter spp. The overall nitrification sequence is as follows N2 O " NHþ 4 ! NH2 OH ! ðNOHÞ
! NO ! NO2 ! NO3
Two nitrogenous gases may evolve through nitrification, NO and N2O. The nitrifiers are active over a wide range of temperatures (2–40 C). The overall nitrification process is controlled primarily by ammonium and
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There is evidence that nitrite produced by nitrifying or denitrifying micro-organisms can also react chemically to form N2O via ‘‘chemodenitrification.’’[8] High nitrite concentrations have been attributed to the inhibition of nitrite oxidation, which is presumed to result from ammonia toxicity to Nitrobacter. Several investigators have noted that gaseous loss of nitrogen (via NO, N2O, or N2) may accompany temporary nitrite accumulation. High concentration of nitrite is sometimes found in anaerobic soils where ammonium and ammonium type fertilizers are applied at high doses. Nitrite ions react chemically with organic molecules forming nitroso-groups (–N¼O) that are unstable.
Other Mechanisms Some of the N2O evolved from soils may be formed by chemical decomposition of hydroxylamine (NH2OH)
Nitrous Oxide Emissions: Sources, Sinks, and Strategies
produced by nitrifying or nitrate-reducing microorganisms, because NH2OH has been identified as an intermediate in oxidation of ammonium to nitrate by Nitrosmonas europeae and has been postulated as an intermediate in microbial reduction of nitrate to ammonium, and several investigations have shown that NH2OH is decomposed rapidly in soils with formation of N2O and N2 by processes that appear to be largely chemical. Other investigations indicated that Mn compounds are involved in the reactions leading to formation of N2O and N2 by chemical decomposition of NH2OH in soils, and that CaCO3 and Fe compounds are involved in the reactions leading to formation of N2 in calcareous soils. The reaction is as follows 2MnO2 þ 2NH2 OH ! 2MnO þ N2 O þ 3H2 O Several workers[1] have postulated that N2O is produced in soils through interaction of hydroxylamine and nitrite produced by soil micro-organisms as follows NH2 OH þ HNO2 ! N2 O þ 2H2 O
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Nitrification Inhibitors Because ammonia and ammonium producing compounds are the main sources of fertilizer nitrogen, maintenance of the applied nitrogen in the ammonium form should result in a lower emission of N2O from cultivated soils. One mechanism of maintaining added ammonium N is to use nitrification inhibitors with the fertilizer. Mosier et al.[12] summarized the effects of nitrification inhibitors on N2O emission from fertilized soils both in laboratory and field studies. A number of field studies indicate that nitrification inhibitors do limit N2O emissions from ammonium-based fertilizers. Several recent field tests also show that the utilization of a variety of nitrification inhibitors does significantly limit N2O emissions from the application of ammonium-based fertilizers. To illustrate this point, a study to quantify the effect of nitrification inhibitors DCS (N-2, 5-dichlorophenyl succinamic acid) and the application of ammonium sulfate on N2O emissions was conducted in field lysimeters using carrot (Daucus carota L.) as a test crop.[11] The addition of DCS reduced about 30% of N2O emission and leaching of nitrate.
Controlled Release Fertilizer MEASUREMENT OF NITROUS OXIDE EMISSION Nitrous oxide emissions from N-fertilized agricultural fields have been found to vary between 0.001% and 6.8% of the N applied to the field.[9–11] A proportion of this variability in N2O estimates, relative to the amount and type of fertilizer applied and to the type of cropping system such as grassland, upland crop, rice paddy, and others, has been attributed to spatial and temporal change in the processes, which produce N2O in soil.
MITIGATION STRATEGY Many of the strategies were proposed by Mosier et al.[12] 1) match N supply with crop demand; 2) close N flow cycles; 3) use advanced fertilizer technologies; and 4) optimize tillage, irrigation, and drainage, in which gaseous emissions deal primarily with cropping systems could be minimized. Although most of the practices listed are assumed to decrease N2O emissions, there have been relatively few systematic studies in which various farming practices were compared as to their ability to conserve N and limit N2O emissions. A number of field studies have been conducted with nitrification inhibitors that could decrease N2O emissions when used. There are a few studies in which the potential of using controlled release fertilizer for decreasing N2O emission was evaluated as follows.
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The use of controlled release fertilizer has the potential to improve N-use efficiency by matching nutrient release with crop demand, reducing NO3 leaching and denitrification losses. Polyolefin-coated fertilizers are a type of controlled release fertilizer where fertilizer granules are covered with a thermoplastic resin. The release of the N fertilizer is temperature dependent and is not controlled by hydraulic reactions or by microbial attack of the coating. Greenhouse studies have revealed that controlled release fertilizer can increase yields with more N-fertilizer use efficiency and reduce NO3 leaching. For example, Minami[11] observed that a controlled release fertilizer reduced N2O emissions in lysimeter studies of carrot at Tsukuba, Japan, in which the fertilizer-induced emissions of N2O–N during an 83 day-period of cultivation were 0.14% and 0.02% of the 250 Kg N applied following ammonium sulfate and a controlled release fertilizer, respectively.
REFERENCES 1. Bremner, J.M. Sources of nitrous oxide in soils. Nutr. Cycling in Agroecosys. 1997, 49, 7–16. 2. IPCC. Climate Change: The IPCC Scientific Assessment; Houghton, J.T., Jenkins, G.J., Ephraume, J.J., Eds.; Cambridge University Press: Cambridge, 1990.
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3. Crutzen, P.J.; Ehhalt, D.H. Effect of nitrogen fertilizers and combustion on the stratospheric ozone layer. Ambio 1977, 6, 112–117. 4. IPCC. In Climate Change 1995, Impacts, Adaptations and Mitigation of Climate Change: Scientific-Technical Analyses; Watson, R.T., Zinyowera, Mos, R.H., Eds.; Cambridge University Press: Cambridge, 1996. 5. IPCC. In Climate Change 1994: Radiative Forcing of Climate Change and an Evaluation of the IPCC IS92 Emission Scenarios; Houghton, J.T., Meira Filho, L.G., Bruce, J., Lee, H., Callander, B.A., Haites, E., Harris, N., Maskell, K., Eds.; Cambridge University Press: Cambridge, 1995. 6. Bouwman, A.F. Direct Emission of Nitrous Oxide from Agricultural Soils, RIVM Report No. 773004004; RIVM: Bilthoven, 1994; 1–28. 7. Bremner, J.M.; Blackmer, A.M. Effects of acetylene and soil water content on emissions of nitrous oxide from soils. Nature 1979, 280, 380–381.
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Nitrous Oxide Emissions: Sources, Sinks, and Strategies
8. Chalk, P.K.; Smith, C.J. Chemodenitrification. In Gaseous Loss of Nitrogen from Plant-Soil Systems; Freney, J.R., Simpson, J.R., Eds.; Martinus Nijhof=Dr W. Junk Publishers: The Hague, 1983; 65–90. 9. Eichner, M.J. Nitrous oxide emissions from fertilized soils: summary of available data. J. Environ. Qual. 1990, 19, 272–280. 10. Bouwman, A.F. Exchange of greenhouse gases between terrestrial ecosystems and the atmosphere. In Soils and the Greenhouse Effect; Bouwman, A.F., Ed.; John Wiley & Sons: New York, 1990; 61–127. 11. Minami, K. Nitrous oxide emissions from agricultural fields. In Trace Gas Emissions and Plants; Singh, S.N., Ed.; Kluwer Academic Publishers: Dordrecht, 2000; 215–230. 12. Mosier, A.R.; Duxbury, J.M.; Freney, J.R.; Heinemeyer, O.; Minami, K. Nitrous oxide emissions from agricultural fields: assessment, measurement and mitigation. Plant Soil 1996, 131, 95–108.
No Till Paul W. Unger United States Department of Agriculture (USDA), Bushland, Texas, U.S.A.
INTRODUCTION No-till, also known as no-tillage or zero-tillage, is a type of conservation tillage, which is a planting system that results in at least 30% cover of crop residues on the soil surface after planting the next crop.[1] Use of conservation tillage provides major soil erosion control benefits and also helps conserve water. In contrast, conventional tillage refers to tillage operations normally used for crop production that bury most residues and result in proteins > cellulose > hemicelluloses > fats, starches, and waxes > lignins and tannins. Mineralization releases soluble or gaseous inorganic constituents during decomposition processes. Humification is a multistage process.[3] Source materials for humus synthesis include residual components from incomplete decomposition of organic litter and the products of microbial anabolic activities. According to present concepts, polyphenols derived from lignin degradation, together with those synthesized by microorganisms, are oxidized to quinones, which undergo self-polymerization or combine with amino compounds to form nitrogen (N)-containing polymers. Sugar-amine condensation reactions may also participate in the formation of humic substances. Accumulation in Organic Soils Paludization can be considered a geogenic rather than pedogenic process because it involves deposition of initial parent material. Paludization occurs when conditions impede decomposition, enabling the buildup of a thick mass of organic deposits. Decomposition is hampered by poorly drained conditions, as in Histosols, and by extreme cold, as in Gelisols. Under anaerobic conditions, humic substances exhibit an accumulation of aromatic carbon (C) compounds arising from the absence of lignin-degrading fungi.[4] Aromaticity can also develop in organic horizons from sources without lignin, such as detritus from algae and mosses. In contrast to paludization, ripening refers to the decomposition processes occurring in the organic horizon under oxidizing conditions after exposure to the air. Surface Accumulation in Mineral Soils
Organic Matter Transformation Decomposition refers to the chemical and biochemical reactions occurring during the decay of plant and animal remains as soil microorganisms colonize them (Fig. 1). Decomposition involves the fragmentation 1172 Copyright © 2006 by Taylor & Francis
Melanization produces thick, dark-colored surface horizons characteristic of Mollisols. The formation of mollic epipedons is promoted by the proliferation of grass roots that constitute a considerable input of plant residues.[5] Another key factor in melanization Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001950 Copyright # 2006 by Taylor & Francis. All rights reserved.
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Table 1 Fundamental pedogenic processes associated with organic matter accumulation Term
Definition
Representative horizon (soil order)
Littering
Accumulation of fresh organic detritus on the mineral soil surface to a depth of 30 cm deep) organic materials on the mineral soil surface
Histic epipedon (Histosols and Gelisols)
Ripening
Changes in organic soil promoted by entry of air into previously waterlogged material
Histic epipedon (Histosols)
Melanization
Darkening of light-colored initial mineral soil by addition of organic matter
Mollic epipedon (Mollisols) Melanic epipedon (Andisols)
Podzolization
Translocation of organic matter in the soil profile associated with Al and Fe migration
Spodic horizon (Spodosols)
(From Ref.[2].)
is the active faunal community, which contributes to the rapid incorporation of the residues into the mineral soil and favors high initial mineralization rates. Subsequent decomposition and humification processes result in the formation of chemically stable, darkcolored humic substances, characterized by a high proportion of high-molecular weight, highly aromatic, acid-insoluble humic acids. Multivalent cations, such as calcium, act as bridges between organic colloids and clay particles, and stabilize organic substances within the soil matrix. In allophanic soils derived from volcanic parent material (Andisols), organic matter accumulation is favored by the formation of resistant organic-alumina complexes.
Subsurface Accumulation Podzolization results in the formation of subsurface horizons of organic matter accumulation characteristic of Spodosols. Subsurface organic matter accumulation occurs at the top of the spodic horizon due to the migration of water-soluble organic compounds from the mineral surface.[6] Soluble organics are composed mainly of polyphenolics and lower molecular weight polymers (fulvic acids), originating from the decomposition processes of nutrient-poor, acidic organic residues, such as heath and coniferous litter. According to the traditional metal–fulvate theory, organometallic complexes form in the decomposing litter under conditions of low metal saturation, complex more iron (Fe) and aluminum (Al) as they flush down the soil profile with percolating water, and precipitate when the ratio of metal to C reaches a critical level. Other proposed
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Fig. 1 Scanning electron micrographs of a fresh (top) and decomposing (bottom) manzanita leaf (magnification: 1000).
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mechanisms for immobilization include flocculation, polymerization, and sorption on mineral surfaces.
ENVIRONMENTAL CONTROLS Climate Climate influences organic matter accumulation by controlling the balance between litter production and decomposition rates. On a global basis, soil carbon content increases with increasing precipitation but decreases with increasing temperature.[7] In situations in which moisture is not a controlling factor, decomposition increases with increasing temperature. Litter production follows the same trend. Therefore, the worldwide accumulation of soil organic matter is related more to factors controlling decomposition than to the productivity of ecosystems. On a local and regional scale, OM content decreases exponentially with rising annual temperature at any given level of precipitation:[1] OM ¼ CekT
ð2Þ
where T is the mean annual air temperature ( C), and C and k are constants. For instance, in North American prairie soils, carbon content decreases two to three times for each 10 C increase in mean annual temperature when other factors are kept constant. On the other hand, organic matter accumulation does not follow a climatic pattern in poorly drained soils where anaerobic conditions impede decomposition processes. In addition to its influence on total C content, climate may also affect the chemical composition of soil organic matter. High rainfall favors high leaching regimes and reduces the development of aromaticity in soil organic matter.[4] Aromaticity also has been reported to be negatively correlated to the precipitation=temperature ratio. For prairie soils of the Great Plains, polysaccharides decrease with increasing temperature but increase with increasing precipitation.[8]
horizon. Coniferous litter, such as pine, tends to be low in nutrients but high in recalcitrant constituents, such as lignin and waxes, and typically decomposes at slower rates than deciduous litter. The chemical composition of litter also exerts a significant influence on the accumulation and turnover of soil organic matter by determining the palatability of the plant material, which in turn can alter the distribution and activity of soil fauna. Soil animals, such as earthworms, may accelerate decomposition rates by contributing to the rapid mixing of fresh plant residues into the mineral soil. Parent Material Parent material may influence organic matter accumulation through its effect on soil fertility. Soils formed from base cation-rich volcanic rocks (e.g., basalt) are typically more fertile, and thus experience more organic matter accumulation than soils with lower inherent mineral-derived nutrients, such as those formed from granitic materials. Parent material is also effective through its determination of soil texture. Soil clay content and organic matter accumulation are positively correlated. Clay content affects soil moisture and water availability, thereby modifying plant productivity and litter production. Additionally, a high clay content may induce organic matter accumulation by stabilizing humic substances formed during decomposition. Clay and organic matter form organomineral complexes that are resistant to further biodegradation. Topography Topography interacts with microclimate to influence organic matter distribution in soils. Organic matter accumulation is often favored at the bottom of hills where conditions are wetter than at mid- or upperslope positions. In a similar fashion, organic matter accumulation is usually greater on north-facing slopes compared with south-facing slopes (in the Northern Hemisphere) because temperature is lower.
Organisms Time The amount, placement, and chemical composition of the organic residues of vegetation also affects organic matter accumulation.[9] Litter production worldwide declines with increasing latitude from tropical to arctic forests, following the same distribution patterns as net primary productivity. The placement of organic residues affects the distribution of organic matter accumulation within the soil profile. In grassland soils, where belowground production is abundant, organic matter is more evenly distributed than it is in forest soils, where most accumulation occurs in the uppermost
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Long-term rates of organic matter accumulation in Holocene-aged soils vary from about 1 to 12 g C m2 yr1.[10] Organic matter, however, does not accumulate indefinitely in soils. Depending on other soil forming factors, an equilibrium level is reached over time. Organic matter encompasses a series of pools with varying turnover rates. Amounts of the young, labile organic matter may level off in decades because plant biomass stabilizes, while amounts of the more recalcitrant fractions, composed of humic
Organic Matter Accumulation
substances often complexed with clay minerals, may continue to increase for tens of thousands of years.
REFERENCES 1. Jenny, H. Factors of Soil Formation; McGraw-Hill: New York, 1941. 2. Buol, S.W.; Hole, F.D.; McCracken, R.J. Pedogenic processes: Internal, soil-building processes. In Soil Genesis and Classification, 3rd Ed.; Iowa State University Press: Ames, 1989; 114–125. 3. Stevenson, F.J. Biochemistry of the formation of humic substances. In Humus Chemistry: Genesis, Composition, Reactions, 2nd Ed.; John Wiley and Sons: New York, 1994; 188–211. 4. Preston, C.M. Applications of NMR to soil organic matter analysis: History and prospects. Soil Science 1996, 161 (3), 145–166.
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5. Oades, J.M. The retention of organic matter in soils. Biogeochemistry 1988, 5, 35–70. 6. Browne, B.A. Towards a new theory of podzolization. In Carbon Forms and Functions in Forest Soils; McFee, W.W., Kelly, J.M., Eds.; Soil Science Society of America: Madison, Wisconsin, 1995; 253–273. 7. Post, W.A.; Emanuel, W.R.; Zinke, P.J.; Stangenberger, A.G. Soil carbon pools and world life zones. Nature 1982, 298 (8), 156–159. 8. Amelung, W.; Flach, K.; Zech, W. Climatic effects on soil organic matter composition in the great plains. Soil Sci. Soc. Am. J. 1997, 61, 115–123. 9. Quideau, S.A.; Anderson, M.A.; Graham, R.C.; Chadwick, O.A.; Trumbore, S.E. Soil organic matter processes: characterization by 13C NMR and 14C Measurements. Forest Ecology and Management 2000, 138, 19–27. 10. Chadwick, O.A.; Kelly, E.F.; Merritts, D.M.; Amundson, R.G. Carbon dioxide consumption during soil development. Biogeochemistry 1994, 24, 115–127.
Organic Matter and Global C Cycle Keith Paustian Colorado State University, Fort Collins, Colorado, U.S.A.
INTRODUCTION
CARBON STOCKS IN SOIL
Soil organic matter (SOM) comprises an integral component of the global carbon (C) cycle, both as the largest overall repository of C within the terrestrial system and as a major source and sink for C exchanges between the atmosphere, terrestrial vegetation, and aquatic environments. Consequently, SOM plays a significant role in regulating the composition of the atmosphere, particularly with respect to carbon dioxide (CO2). Thus, there is both concern that the effects of climate and land use change on soils will exacerbate the problem of increasing CO2 in the atmosphere and hope that through better management, soils can play a part in mitigating increasing CO2 levels.
Carbon comprises a relatively minor component of most soils, in terms of mass. Most soils contain from 1% to 10% C by mass in surface horizons, with the majority having C contents in the range of 1–3%. The most notable exceptions are soils formed under waterlogged conditions, which restricts the flow of oxygen to soil organisms, greatly reducing the rates of SOM decay. Such organic soils or ‘‘histosols’’ may contain 10–30% or more of their total dry mass as C. Despite this generally low concentration, on an area basis, the C contained in soils usually exceeds that contained in the living and dead vegetation (Table 1). Estimates of the global C stock in soils vary, although most recent estimates are on the order of 1400–1600 Pg (Petagram ¼ 1015 g ¼ billion metric tonnes) organic C[2,3] and 700–900 Pg inorganic C.[4] Concentrations of organic C are highest in wetlands and in cold, wet environments (e.g., boreal forest) where decomposition rates are suppressed, and are lowest in desert and tundra soils where plant productivity, and hence C additions to soil, is low. Stocks of inorganic C are greatest in desert and semiarid to subhumid grasslands and savannas, where carbonate leaching is restricted and the formation of secondary carbonate minerals is favored.
CARBON COMPONENTS OF SOIL Carbon is present in both inorganic and organic forms in soil. With the exception of some soils formed on carbonate-rich parent material or arid soils containing high levels of primary or secondary carbonates, organic forms of C predominate in soil. These organic compounds range from fresh plant residues— which are the primary source of SOM—to highly recalcitrant, amorphous humic substances. Plant residues are broken down by the soil biota, chiefly microorganisms, to derive energy (i.e., respiration) and C and nutrient elements needed to grow and reproduce. The soil biota comprise a complex food web in which microbial-, plant-, and animal-derived materials are continually consumed, decomposed, and reformed as soil biomass and other secondary compounds. Plant compounds that are not fully metabolized by the biota, e.g., lignin derivatives, microbial metabolites and other organic substances, can also recombine through chemical and physical reactions. Thus, the decomposition process can be viewed as a ‘‘cascade’’ of biophysiochemical reactions and products,[1] resulting in the loss of C via respiration, together with the formation of a wide array of secondary SOM compounds including complex recalcitrant substances which can persist in soil for several hundreds to thousands of years. 1176 Copyright © 2006 by Taylor & Francis
CARBON FLUXES The CO2 exchanges between the atmosphere, vegetation, and soils are among the largest annual fluxes in the global C cycle (Fig. 1), which are clearly detectable in the regular, seasonal variations in atmospheric CO2 concentrations. Global estimates of net primary production, expressed as C assimilated by live plants (minus respiration) are on the order of 60 Pg C=yr.[5] Much of the annually produced biomass is added to the soil and soil-surface each year as senesced leaves, roots, and woody debris. Emissions of CO2 from soils through decomposition processes (via heterotrophic respiration) are thought to be on the order of 50 Pg=yr with additional losses of about 10 Pg=yr from disturbances such as fire.[5] If terrestrial biome C stocks were at equilibrium, then additions of C through net Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001824 Copyright # 2006 by Taylor & Francis. All rights reserved.
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Table 1 Global carbon stocks in soil and vegetation by major biome types Area (106 km2)
Average C density (Mg ha1)
Soil C stock (Pg)
Vegetation C stock (Pg)
Tropical forests
17.6
Temperate forests
10.4
123
216
212
96
100
59
Boreal forests Tropical savannas
13.7
344
471
88
22.5
117
264
66
Temperate grasslands
12.5
236
295
9
Deserts and semi-deserts
45.5
42
191
8
Biome
Tundra
9.5
13
121
6
Wetlands
3.5
642
225
15
16.0
80
128
3
—
2011
466
Croplands Total
151.2
(Adapted from Ref.[5].)
primary production would be fully balanced by losses through decomposition and other emission sources such as fire. However, overall estimates of the global C cycle suggest that a net accumulation of C presently occurs in terrestrial vegetation and soils, at a rate of about 2 Pg C=yr (Table 2). During the 1980s, tropical regions are believed to have been a net source of C emissions, largely through deforestation. Similar global estimates for the 1990s have not yet been reported, but if the tropics remain a net source of C from deforestation then the size of the present-day terrestrial sink outside the tropics would be correspondingly greater. In the global budget, the terrestrial sink term is calculated as a difference between the estimates of fossil C emissions, ocean uptake, and observed increases in
Fig. 1 Simplified depiction of the global carbon cycle. Total stocks of carbon in the atmosphere (as CO2), oceans, vegetation and soils þ detritus are shown in bold and approximate annual gross fluxes between the major biosphere pools are shown in italics. Dashed arrows denote direction and magnitude of the net flux of CO2 from industrial sources (mainly fossil fuel combustion) and net sinks to terrestrial and marine environments, estimated as averages for 1990–1999. All stock values are in units of Pg (i.e., billion metric tonnes) and fluxes are Pg=yr. (Adapted from Refs.[5,14,24].)
Copyright © 2006 by Taylor & Francis
atmospheric CO2. The existence and relative size of the inferred terrestrial sink are broadly consistent with estimates of a northern hemisphere terrestrial sink, based on atmospheric transport models[6]—although considerable uncertainty as to the magnitude and geographic distribution of the sink remains.[7]
SOIL CARBON FLUXES AND GLOBAL CHANGE While the net terrestrial accumulation of C is small relative to the annual fluxes of C between the atmosphere and land, it is extremely significant in relation to the net change in CO2 in the atmosphere. In other words, if the terrestrial C sink was to disappear, and everything else remained equal, the rate of growth of CO2 in the atmosphere would increase by more than 50%, from about 3.2 to over 5 Pg=yr (Table 2). The origin of and controls on this terrestrial C sink are not well understood. Model estimates[8] attribute much of the sink to increased plant growth rates due to higher CO2 concentrations, although other factors such as N deposition and changing land use contribute as well. The contribution of soils to the overall C sink is still uncertain although it is hypothesized that most of the C accumulates as biomass and surface litter pools. In part, this is to be expected due to the lag time between C accumulation in biomass and fresh residue pools, and its subsequent appearance in more stabilized SOM pools, as well as the fact that much of the C added to soils is relatively rapidly decomposed and evolved as CO2. Global accumulation of refractory humic compounds in mature native ecosystems has been estimated at 0.4 Pg=yr and it has been suggested that these increases roughly balance leaching losses and long-term average organic C transfers to oceans.[9] Soil C increases attributed to global afforestation and
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Table 2 Major net sources and sinks of C in the global budget for the 1980s and 1990s 1980–1989
1990–1999
Atmospheric increase in CO2-C
3.3 0.1
3.2 0.1
Emission of C from fossil fuel and cement
5.4 0.3
6.3 0.3
Ocean–atmosphere flux
1.9 0.6
1.7 0.3
Land–atmosphere flux (Net from land use change) (Net from other terrestrial sinks)
0.2 0.7 [1.7 (0.6–2.5)]
1.4 0.3 NAa
[1.9 (3.8–0.3)]
NA
a
Not available. (Adapted from Ref.[24].)
However, this legacy of past land use offers an opportunity to reverse the historical trend and through better management of soils, exploit their potential to become a significant sink for CO2. A variety of management options are available to increase soil C storage in agricultural[23] and other managed ecosystems.[5] Recent estimates suggest that potential C sequestration through improvements in land use and management, globally, is on the order of 1 Pg=yr.[5] Thus the role of SOM in the global C cycle, and how it will respond to future changes in climate and land use, will be determined by both the natural forces regulating the Earth’s biosphere as well as the social, economic, and political actions of human kind.
REFERENCES forest regrowth since the 1950s are estimated to be on the order of 0.1 Pg=yr.[10] Global estimates are still lacking for other ecosystems, but recent inventories for the U.S.[11] suggest that soils in cropland and grazing land currently represent a small sink, on the order of 10–30 Tg=yr (Teragram ¼ 1012 g ¼ million metric tonnes), which can be compared to estimates for C increases in U.S. forest biomass of about 210 Tg=yr.[12] The potential feedbacks of climate change on soil C stocks are currently being debated. Since both plant production (hence, C inputs) and decomposition (hence, C losses) are affected by changes in temperature, precipitation, and CO2 concentrations, the interactions and feedbacks controlling the terrestrial C balance are complex and difficult to predict. Earlier estimates, assuming a stimulation of decomposition due to projected increases in temperature, suggested that soils could become a significant net source of CO2, on the order of 40–60 Pg over a 50–100 yr period, under a climate regime predicted for double presentday CO2 concentrations.[13,14] Other studies suggest that including positive effects of CO2 on plant productivity, management, together with adaptations in land might largely offset climate-driven increases in decomposition potential.[15,16] Recent debates[17–19] have highlighted the complexity and continuing uncertainty of how temperature increase, and other changes in climate and CO2, may impact soils and the global C cycle. The other significant driver of soil C changes, both past and future, is land use and management. It is well established that the conversion of native ecosystems (e.g., forests, grasslands, wetlands), primarily to agricultural uses, has led to significant losses of C from terrestrial ecosystems, on the order of 120–170 Pg C or more over the past 150–300 yr from vegetation and soils combined.[20] From soils alone, estimates of historical losses over the same period are 50–100 Pg C.[21,22]
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1. Swift, M.J.; Heal, O.W.; Anderson, J.M. Decomposition in Terrestrial Ecosystems; Blackwell Press: Oxford, UK, 1979; 372 pp. 2. Post, W.M.; Emanuel, W.R.; Zinke, P.J.; Stangenberger, A.G. Soil carbon pools and world life zones. Nature 1982, 298, 156–159. 3. Eswaran, H.; Van Den Berg, E.; Reich, P. Organic carbon in soils of the world. Soil Sci. Soc. Am. J. 1993, 57, 192–194. 4. Eswaran, H.; Reich, P.F.; Kimble, J.M.; Beinroth, F.H.; Padmanabhan, E.; Moncharoen, P. Global carbon stocks. In Global Climate Change and Pedogenic Carbonates; Lal, R., Kimble, J.M., Eswaran, H., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 2000; 15–25. 5. IPCC. Land Use, Land Use Change, and Forestry, Intergovernmental Panel on Climate Change Special Report; Cambridge University Press: Cambridge, UK, 2000; 377 pp. 6. Tans, P.P.; Fung, I.Y.; Takahashi, T. Observational constraints on the global atmospheric carbon dioxide budget. Science 1990, 247, 1431–1438. 7. Field, C.B.; Fung, I.Y. The not-so-big US carbon sink. Science 1999, 285, 544–545. 8. McGuire, A.D.; Sitch, S.; Clein, J.S.; Dargaville, R.; Esser, G.; Foley, J.; Heimann, M.; Joos, F.; Kaplan, J.; Kicklighter, D.W.; Meier, R.A.; Melillo, J.M.; Moore, B., III; Prentice, I.C.; Ramankutty, N.; Reichenau, T.; Schloss, A.; Tian, H.; Williams, L.J.; Wittenberg, U. Carbon balance of the terrestrial biosphere in the twentieth century: analysis of CO2, climate and land use effects with four process-based ecosystem models. Glob. Biogeochem. Cycles 2001, 15, 183–206. 9. Schlesinger, W.H. Evidence from chronosequence studies for a low carbon-storage potential of soils. Nature 1990, 348, 232–234. 10. Post, W.M.; Kwon, K.C. Soil carbon sequestration and land-use change: processes and potential. Global Change Biol. 2000, 6, 317–327. 11. Eve, M.D.; Paustian, K.; Follett, R.; Elliott, E.T. A national inventory of changes in soil carbon from national resources inventory data. In Methods of
Organic Matter and Global C Cycle
12.
13.
14.
15.
16.
17.
18.
Assessment of Soil Carbon; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 2001; 593–610. US Environmental Protection Agency. Inventory of US Greenhouse Gas Emissions and Sinks: 1990–1998; US EPA 236-R-00-001; US EPA: Washington, DC, 2000. Jenkinson, D.S.; Adams, D.E.; Wild, A. Model estimates of CO2 emissions from soil in response to global warming. Nature 1991, 351, 304–306. Schlesinger, W.H. An overview of the carbon cycle. In Advances in Soil Science: Soils and Global Change; Lal, R., Kimble, J., Levine, E., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1995; 9–25. Prentice, K.C.; Fung, I.Y. The sensitivity of terrestrial carbon storage to climate change. Nature 1990, 346, 48–51. Paustian, K.; Elliott, E.T.; Peterson, G.A.; Killian, K. Modelling climate, CO2 and management impacts on soil carbon in semi-arid agroecosystems. Plant Soil 1996, 187, 351–365. Giardina, C.P.; Ryan, M.G. Evidence that decomposition rates of organic carbon in forest mineral soil do not vary with temperature. Nature 2000, 404, 858–861. Davidson, E.A.; Trumbore, S.E.; Amundson, R. Soil warming and organic carbon content. Nature 2000, 408, 789–790.
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19. Thornley, J.H.M.; Cannell, M.G.R. Soil carbon storage response to temperature: a hypothesis. Ann. Bot. 2001, 87, 591–598. 20. Houghton, R.A. The annual net flux of carbon to the atmosphere from changes in land use 1850–1990. Tellus 1999, 51B, 298–313. 21. IPCC. Climate change 1995: chapter 23 – agricultural options for mitigation of greenhouse gas emission impacts. In Adaptations and Mitigation of Climate Change: Scientific–Technical Analyses; Intergovernmental Panel on Climate Change (IPCC) Working Group II; Cambridge University Press: Cambridge, UK, 1996; 745–771. 22. Lal, R. Soil Management and restoration for carbon sequestration to mitigate the accelerated greenhouse effect. Prog. Environ. Sci. 1999, 1, 307–326. 23. Paustian, K.; Collins, H.P.; Paul, E.A. Management controls on soil carbon. In Soil Organic Matter in Temperate Agroecosystems; Long-Term Experiments of North America; Paul, E.A., Paustian, K., Elliott, E.T., Cole, C.V., Eds.; CRC/Lewis Publishers: Boca Raton, FL, 1997; 15–49. 24. IPCC. Climate change 2001: the scientific basis. In Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change (IPCC); Houghton, J.T., Yihui, D., Eds.; Cambridge University Press: Cambridge, UK.
Organic Matter and Nutrient Dynamics Charles W. Rice Kansas State University, Manhattan, Kansas, U.S.A.
INTRODUCTION Soil organic matter (SOM) is a fundamental component of soil and the global carbon (C) cycle. Soil organic matter controls many of the chemical, physical, and biological properties of the soil.[1] The estimated amount of organic C stored in world soils is about 1100–1600 Pg, more than twice the C in living vegetation (560 Pg) or in the atmosphere (750 Pg).[2] Hence, even relatively small changes in soil C storage per unit area could have a significant impact on the global C balance. Soil organic matter is derived mostly from plant residues. Plants convert CO2 into tissue through photosynthesis. Upon their death, plant tissues decompose, primarily by soil microorganisms, and most of the C in the plant material is eventually released back into the atmosphere as CO2. Between 10% and 20% of the C in plant residue forms SOM, sometimes referred to as ‘‘humus.’’ Some of this C can persist in soils for hundreds and even thousands of years. Associated with the C in soil organic matter are many essential plant nutrients—primarily N, P, and S. Concentrations of soil organic matter range from 0.2 to over 80% in peat soils although the typical range for temperate soils is 0.4–10%.[3] While it is a minor component of most soils, SOM is essential to the living component of soil. Soil organic matter provides the energy source for most soil microorganisms, and provides the nutrient for plants and the soil biological community. Thus, knowledge of SOM dynamics is crucial for the understanding of global C cycling and plant production. The accumulation of SOM is dependent on the quantity and quality of organic residue inputs, largely as plant material, the rates of microbial decomposition, and the capacity of the soil to store organic matter. The quality of the plant residue affects both the extent and rate of decomposition. Labile C compounds such as simple sugars degrade relatively rapidly and more completely to CO2. On the other end of the spectrum, lignin is more difficult to degrade. Most microorganisms do not have the capacity to completely degrade lignin to CO2. Thus, many of the partial degradation products form the precursors to soil organic matter. Generally, the C : N ratio is a guide of decomposability. A ratio >30 slows decomposition and immobilizes N; a ratio 250 mm provide the greatest protection.[5,6]
COMPOSITION Soil organic matter is not one definable entity. Since SOM is formed from plant material and microbial decomposition products, it is a myriad of organic compounds. There have been several theories on the formation of soil humus but the most widely accepted theory is that organic residues undergo decomposition by microorganisms.[7] The altered compounds and new compounds synthesized by soil microbes polymerize through chemical or enzymatic reactions. Thus, SOM is undergoing constant transformation. Typically, most soil organic models define three pools of SOM (Fig. 1). The active pool, which is comprised of microbial biomass and labile organic compounds makes up less than 5% of the soil organic C. The slow pool usually makes up 20–40% of the total organic C and the recalcitrant pool makes up 60–70% of the soil C. These fractions Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120002258 Copyright # 2006 by Taylor & Francis. All rights reserved.
Organic Matter and Nutrient Dynamics
Fig. 1 Schematic of plant decomposition through microbial biomass in the formation of soil organic matter. (Adapted from Ref.[7].)
are often defined kinetically based on laboratory mineralization.[5,8] Microbial biomass is the processor and the slow pool is the one in which much of the plant-associated nutrients reside for mineralization. The recalcitrant pool is material that is difficult to degrade and contains what in the older literature was known as humic and fulvic acids—fractions obtained by chemical-fractionation procedures. The active pool has turnover times on the order of months to years, the slow pool takes decades to turn over, while C in the recalcitrant pool takes from hundred to thousands of years to turn over completely. However, 2–5% of the recalcitrant pool is degraded annually. Since the recalcitrant pool is generally in equilibrium in natural systems, then the rate for formation equals the rate of degradation.
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N as inorganic N from the soil can be a significant source of N to satisfy plant needs. This process is called net N mineralization, which is the sum of two simultaneous processes, N mineralization and N immobilization. Nitrogen mineralization, or more correctly called ‘‘ammonification,’’ is the conversion of organic N to ammonium. Nitrogen immobilization is the conversion of ammonium to organic N. Microorganisms control both these processes, thus factors that regulate microbial activity, as described earlier, will impact N availability.[9] In addition to environmental factors, the quality of the organic substrate for microorganisms is important. Low-quality substrate, i.e., high C : N ratio, microorganisms degrading the residue require additional nutrients, primarily N. As a result, soil microorganisms assimilate or immobilize inorganic N. Plants may become deficient in N as the microbes fulfill their N need during decomposition of high C : N residue. Later as the organic material is processed, the N previously assimilated by microorganisms is re-released as inorganic N and can become available to plants. Often the release of organic N to the inorganic forms is in synchrony with plant uptake since favorable temperatures and water availability that promote microbial activity also promote plant growth.[9,10] In most native ecosystems and organic agriculture, N mineralization is the major source of plant N needs. In cropland as much as 11–300 kg N ha1 can be supplied from organic matter.[11] Further biological transformations of N occur in the soil, including nitrification (oxidation of NH4þ to NO3) and denitrification (conversion of NO3 to N2); however, these are not directly linked to SOM and will not be discussed in this section. Please refer to Sylvia et al.[12] for further discussion.
NUTRIENTS Along with carbon, SOM contains important plant nutrients. Soil organic matter can be a source or sink of plant nutrients. Plant productivity is directly associated with SOM content and turnover. Approximately 90–95% of the soil N, 40% of the soil P, and 90% of the soil S is associated with SOM.[3] Generally, the C : N : P : S ratio is 100 : 10 : 1 : 1. In agricultural soils, approximately 2–4% of the organic matter is rendered available for plant uptake on an annual basis. As discussed earlier, the more active pools of SOM are likely to be the major source of plant nutrients.
Nitrogen The plant nutrient that is needed from soil in the greatest quantities is N. Approximately 90–95% of the soil N is in the organic form. The net release of organic
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Phosphorus and Sulfur Sulfur follows similar transformations as N. P is more controlled by soil chemistry and chemical transformations. Thus, SOM is not usually a major source of P by plants, except in very high organic soils. However, organic P can represent 80% of the total P in some soils. Significant amounts of P and S are contained within the microbial biomass. As a rule, a C : S or C : P ratio greater than 60 promotes immobilization of S and P into the microorganisms. Because of the importance of SOM to the quality of the soil and plant productivity, an understanding of SOM dynamics is critical to preserve natural ecosystems and ensure the long-term productivity of managed ecosystems. Gains and losses of SOM have added significance because it is a reservoir for global C and the associated interaction with climate change.
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Table 1 Land use for C sequestration Management strategies Land use
Soil management
Crop management
Cultivation
Tillage
Varieties
Rangeland
Residue management
Crop rotations
Forestry
Fertility Water management Erosion control
Cover crops
(Adapted from Ref.[13].)
MANAGEMENT OF SOM TO ENHANCE SOIL QUALITY
Fig. 2 Relationship between SOM and soil, water, and air quality. (Adapted from Ref.[14].)
Agriculture in the 1800s and early 1900s relied upon the plowing the soil with low crop yields and crop residues were often removed. This combination of agricultural practices resulted in reducing the replenishment of organic C to the soil. Approximately, 50% of the SOM has been lost from soil over a period of 50–100 yr of cultivation. In recent decades, higher yields, return of crop residues, and development of conservation tillage practices have increase SOM. Table 1 lists several practices affecting the soil’s ability to sequester C.[13] Examples of rates of soil C increases are summarized in Table 2.[14] Nitrogen management that increases crop productivity results in an increase in SOM.[15] Nitrogen fertilizer applied at recommended rates for 10 yr increase soil C approximately 2 MT C ha1. Grassland systems also can contribute to C sequestration when properly managed. Under elevated atmospheric CO2, the soil contained 6% more C to a depth of 15 cm compared with ambient conditions.[16] The increase in soil C was due to increased plant production followed by incorporation into the soil. The amount of C sequestered over the 8 yr experimental period was equivalent to 4 Mg ha1. Proper fire management may also increase soil C.[17] Managing agricultural soils for sequestering C will result in additional benefits. Increasing soil organic C include increased crop productivity and enhanced soil,
Table 2 Estimates of C sequestration potential of agricultural practices of U.S. cropland Agricultural practice Conservation Reserve Program
(MTC/ha/yr) 0.3–0.7
Conservation tillage
0.24–0.40
Fertilizer management
0.05–0.15
Rotation with winter cover crops
0.1–0.3
Summer fallow elimination
0.1–0.3
[14]
(Adapted from Ref.
.)
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water, and air quality (Fig. 2). In addition, management practices that increase soil C also tend to reduce soil erosion, reduce energy inputs, and improve soil resources.
REFERENCES 1. Doran, J.W.; Parkin, T.B. Defining and assessing soil quality. In Defining Soil Quality for a Sustainable Environment; Doran, J.W., Coleman, D.C., Bezdicek, D.F., Stewart, B.A., Eds.; [Spec. Publ 35]; Soil Sci. Soc. Am.: Madison, WI, 1994; 3–24. 2. Sundquist, E.T. The global carbon dioxide budget. Science 1993, 259, 934–941. 3. Smith, J.L.; Lynch, J.M.; Bezdicel, D.F.; Papendick, R.I. Soil organic matter dynamics and crop residue management. In Soil Microbial Ecology; Metting, B., Ed.; Marcel Dekker: New York, NY, 1992; 65–94. 4. Linn, D.M.; Doran, J.W. Effect of water-filled pore space carbon dioxide and nitrous oxide production in tilled and nontilled soils. Soil Sci. Soc. Am. J. 1984, 48, 1267–1272. 5. van Veen, J.A.; Paul, E.A. Organic C dynamics in grassland soils. 1. Background information and computer simulations. Can. J. Soil Sci. 1981, 61, 185–201. 6. Jastrow, J.D.; Miller, R.M. Soil aggregate stabilization and carbon sequestration: feed backs through organomineral associations. In Soil Process and the Carbon Cycle; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; CRC Press: New York, 1996; 207–223. 7. Paul, E.A.; Clark, F.E. Soil Biology and Biochemistry; Academic Press: San Diego, CA, 1996. 8. Rice, C.W.; Garcia, F.O. Biologically active pools of soil C and N in tallgrass prairie. In Defining Soil Quality for a Sustainable Environment; Doran, J.W., Coleman, D.C., Bezdicek, D.F., Stewart, B.A., Eds.; [Spec. Publ 35]; Soil Sci. Soc. Am.: Madison, WI, 1994; 201–208.
Organic Matter and Nutrient Dynamics
9. Rice, C.W.; Havlin, J.L. Integrating mineralizable N indices into fertilizer N recommendations. In Soil Testing: Prospects for Improving Nutrient Recommendations; [Spec. Pub. No. 40]; Havlin, J.L., Jacobsen, J.S., Eds.; Soil Sci. Soc. Am.: Madison, WI, 1994; 1–13. 10. McGill, W.B.; Meyers, R.J.K. Controls on dynamics of soil and fertilizer nitrogen. In Soil Fertility and Organic Matter as Critical Components of Production Systems; Follett, R.F., Stewart, J.W.B., Cole, C.V., Eds.; [Spec. Pub. No. 19]; Soil Sci. Soc. Am.: Madison, WI, 1987; 73–99. 11. Smith, J.L.; Paul, E.A. The significance of soil microbial biomass estimations. Soil Biochem. 1990, 6, 357–396. 12. Sylvia, D.M.; Fuhrman, J.F.; Hartel, P.G.; Zuberer, D.A. Principles and Application of Soil Microbiology; Prentice Hall: Upper Saddle River, NJ, 1998. 13. Lal, R.; Kimble, J.R.; Follett, R.F.; Cole, C.V. The Potential of U.S. Cropland to Sequester Carbon and
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Mitigate the Greenhouse Effect; Ann Arbor Press: Chelsa, MI, 1998. Lal, R.; Follett, R.F.; Kimble, J.; Cole, C.V. Managing U.S. cropland to sequester carbon in soil. J. Soil Water Conserv. 1999, 54, 374–381. Espinoza, Y. Dynamics and Mechanisms of Stabilization of C and N in Soil. Ph.D. dissertation, Kansas State Univ. Williams, M.A.; Rice, C.W.; Owensby, C.E. Carbon and Nitrogen dynamics and microbial activity in tallgrass prairie exposed to elevated CO2 for 8 years. Plant and Soil 2000, 227, 127–137. Rice, C.W.; Owensby, C.E. Effects of fire and grazing on soil carbon in rangelands. In The Potential of U.S. Grazing Lands to Sequester Carbon and Mitigate the Greenhouse Effect; Follet, R., Ed.; Lewis Publishers: Boca Raton, 2000; 323–342.
Organic Matter in the Landscape Henry H. Janzen B. H. Ellert Agriculture and Agri-Food Canada, Lethbridge, Alberta, Canada
D. W. Anderson Department of Soil Science, University of Saskatchewan, Saskatoon, Saskatchewan, Canada
INTRODUCTION Soil organic matter is composed largely of plant tissues decomposing back to the simple molecules from which they were first formed: carbon dioxide, ammonium, water, and various salts. Although often present in large amounts, organic matter is transient—new litter is continually being added, and organic matter already present is always decomposing. So at any time, the amount present reflects the net balance between additions and losses. Both inputs and losses at a site depend on conditions there. Litter inputs from plant growth and decomposition are both influenced by many factors: temperature, moisture, aeration, nutrients, plant community, and more. And wind and water move organic matter-laden soil about the landscape. So the amount and composition of organic matter differs from place to place in the landscape. Organic matter varies in several dimensions: It varies vertically within the profile, and horizontally across the landscape. It changes across time, often by human influence. How organic matter is distributed over the landscape may be as important as its amount in affecting the way an ecosystem behaves.[1] In this review, we describe how organic matter is distributed in ‘‘natural’’ landscapes, show how human activities can alter that pattern, and illustrate with a few examples how organic matter distribution (and redistribution) can affect ecosystem function. ORGANIC MATTER IN LANDSCAPES UNAFFECTED BY HUMAN ACTIVITY Vertical Distribution In most soil profiles, organic matter (or organic carbon) concentration is highest near the surface, where most plant litter is added, and then declines with increasing depth.[2,3] In grasslands, globally, the surface 0.2 m of soil accounts for 42% of the organic carbon in the first 1 m; in shrublands, the proportion is 33% and in forests, it is 50%.[4] 1184 Copyright © 2006 by Taylor & Francis
The rate of organic matter turnover also changes with depth. Compared to that deeper in the profile, surface soil usually has higher proportions of ‘‘young’’ organic matter from recent inputs of plant litter. Radiocarbon studies show that the mean turnover time or radiocarbon ‘‘age’’ of organic matter usually increases with depth.[5–7] Lateral Distribution The amount of organic matter in the soil at a given spot is the result of a complex interaction, over time, of parent material, climate, vegetation, and topography.[8] Among landscapes, at regional scales, organic matter content is controlled largely by precipitation, temperature, soil texture, and vegetation type.[9,10] But within a landscape, organic matter is also influenced by other factors. Topography, through effects on microclimate and water movement, can produce soils of widely different organic matter within meters (Fig. 1).[9,11] Usually, the amount of organic matter is lowest near summits, and highest in toeslope positions.[12–14] This pattern occurs for various reasons:[13,15,16] higher moisture and nutrient status downslope increase litter production; organic matter in lower slope positions may decompose more slowly because of soil conditions (e.g., reduced aeration or accumulated clay); variations in microclimate produce different plant communities across topographical gradients; and erosion may move organic matter downhill. Apart from topography, localized variations in texture, soil chemistry, vegetation,[1,17] and other properties may also cause organic matter to vary within landscapes. Even in landscapes that appear uniform, therefore, soil organic matter content varies significantly over scales of several meters. Tiessen and Santos[18] observed coefficients of variation greater than 50% in organic carbon and total nitrogen concentrations in the surface soil of a tropical semiarid field (65 40 m2) immediately after clearing. Organic matter varies across landscapes not only in amount but also in form. For example, Paul et al.[5] observed that radiocarbon ‘‘age’’ of surface soil Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120002259 Copyright # 2006 by Taylor & Francis. All rights reserved.
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Converting grass- and forestlands to arable agriculture, for example, typically results in the loss of about 30% of the organic carbon originally present in the solum.[23] But with better land management, at least part of the organic matter lost can be restored.[24] Human influence on soil organic matter—whether it leads to losses or gains—is rarely uniform over the landscape. Thus, human intervention often alters not only the amount of organic matter, but also its distribution over the landscape. The rearrangement can occur in several ways. Patchwork Application of Practices
Fig. 1 An illustration of variability in soil organic carbon in transects across two toposequences, a native grassland and an agricultural field cultivated for about two decades. Organic matter is about 58% carbon, by weight, so it is often measured as organic carbon. (Adapted from Ref.[28].)
increased from toeslope to summit positions at two uncultivated grassland sites. And Schimel et al.[15] found that the relative mineralization rate of organic matter (N mineralized per unit of total nitrogen) decreased downslope, even though total mineralization increased, pointing to differences in organic matter quality. Temporal Distribution Organic matter in the landscape also changes with time. Soils in early stages of development accumulate organic matter, but the rate of build-up slows as soils approach a steady state, where decomposition roughly balances litter inputs.[19] Even then, however, organic matter fluctuates during a year because litter additions follow a different pattern from decomposition. It also fluctuates from year to year with changes in weather: in some periods, when litter inputs exceed losses, organic matter accumulates; in others, it is depleted.[20] HUMAN INFLUENCE ON DISTRIBUTION Human activities can profoundly alter soil organic matter content. Historically, disturbance of ‘‘natural’’ ecosystems has almost always resulted in losses.[21,22]
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Land practices are often not applied uniformly over the landscape. Forests may be cut in patches; diverse cropping practices may be used in scattered patterns in agricultural landscapes; organic materials such as manures, derived from large, far-flung areas, may be funneled into small areas;[25] grazing animals may congregate near water or shade, depositing organic matter there.[26] These, and other practices applied nonuniformly, can redistribute organic matter on the landscape. Nonuniform Effects on C Balance Even where the same management practice or land use change is applied uniformly over a large area, its effect on organic matter may vary from place to place because the landscape is not uniform to begin with. For example, Schimel, Coleman, and Horton[27] observed that proportional losses of organic matter after cultivating grassland were higher in upper- than in lower-slope positions. And the mechanism of organic matter loss, whether by erosion or biological mineralization, may also vary among slope positions.[28] Tillage Farmers cultivate soils to control pests, prepare land for seeding, and bury residues. This tillage dilutes organic matter-rich soil near the surface by mixing it with soil from deeper layers.[14] It may also affect organic matter deeper in the profile by altering rooting patterns, leaching, faunal activity, and soil temperature.[29,30] Consequently, tillage changes organic matter distribution in the profile, even though total amount may not always be affected.[31] Tillage also alters lateral distribution of organic matter by physically ‘‘dragging’’ topsoil. Each tillage pass moves soil, but the extent of movement is greater downslope than upslope, so that over the years, tillage moves soil and organic matter to lower-slope positions.[32]
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Erosion Globally, the predominant human influence on distribution of organic matter in the landscape is via erosion, especially in deforested and agricultural lands. Although erosion is a natural process and occurs also in undisturbed ecosystems, human disturbance may increase erosion by orders of magnitude.[33,34] Erosion affects organic matter at a site within the landscape in three ways;[11] it may: remove organic matter; result in mixing of subsoil into the surface layer by stripping surface soil away; or result in deposition of soil eroded from elsewhere in the landscape. The effects of erosion are not uniform across the landscape. Highest losses usually occur from convex uplands or ‘‘shoulder elements.’’[11,13] Much of the eroded soil removed from one location in the landscape may be deposited nearby, especially, in closed watersheds.[35] But areas of net removal are usually larger than areas of deposition so that erosion often increases the variability of organic matter on the landscape. This is compounded by selective translocation of soil fractions rich in organic matter.[14,36] The net effect, therefore, is often a removal of organic matter from widespread areas in the landscape and its deposition in low-lying areas. Erosion not only affects directly the distribution of organic matter on the landscape, but may also have long-lasting secondary consequences through effects on plant growth and litter input.[14] While erosion can result in extensive translocation of organic matter, its net effect on total amount stored in the landscape is not always clear. If erosion suppresses productivity, thereby limiting replenishment of organic matter, the organic matter may spiral downwards over the long term. But when productivity of eroded areas can be restored, the eroded landscape might eventually contain more organic matter than before, because of the higher storage potential of eroded areas[37] and the accumulated and buried organic matter in depositional areas.[14] Disruption and management of ecosystems by humans often alter irreversibly the amount and distribution of organic matter in landscapes, often increasing variability on the landscape (e.g., Fig. 1).[38] Our understanding of this redistribution is still incomplete.[39,40]
IMPLICATIONS The heterogeneity of organic matter in the landscape, and its further rearrangement by human activity, determine how ecosystems function. To illustrate, we present three examples. First, the spatial variability of organic matter influences productivity on the landscape. Plant productivity
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Organic Matter in the Landscape
is closely linked to organic matter;[41] consequently, landscapes with variable organic matter usually show corresponding heterogeneity in productivity (whether high organic matter increases productivity or high productivity increases organic matter is not always clear). In farmlands, therefore, increasing attention has been devoted recently to ‘‘site-specific farming’’—adjusting practices spatially to compensate for variability in organic matter and related soil properties.[42] Secondly, the way organic matter is distributed across the landscape influences the unintended release of nutrients into the broader environment. For example, organic matter affects transformations of nitrogen, both as a source of mineralized nitrogen and by effects on microbial activity. Consequently, nitrate leaching or nitrous oxide emissions may be linked to organic matter distribution, especially since sites where organic matter accumulates may also have high moisture.[43,44] Thirdly, the heterogeneity of organic matter within the landscape makes it harder to measure changes in carbon storage. Soil organic matter has been proposed as a potential ‘‘sink’’ for carbon; widespread adoption of practices that build organic matter could increase carbon storage in soils, mitigating the increases in atmospheric CO2 linked to global warming.[45] But to quantify that ‘‘sink’’ precisely, organic matter distribution across the landscape would have to be taken into account; differences in organic matter among points on the landscape are usually much greater than the expected response to new management.[46] At one location, Garten and Wullschleger[47] estimated that more than 100 samples would need to be taken to detect a change in soil organic carbon of about 1 Mg C ha1. The redistribution of organic matter by erosion makes measuring of the carbon sink even more complicated.[48] When erosion occurs during the measurement interval, it may be hard to distinguish carbon exchanged with the atmosphere from that merely redistributed on the landscape. The topsoil, enriched in organic matter, forms a veneer over the landscape, one that varies from place to place and year to year. The performance and persistence of ecosystems depend on this thin layer. And how that layer varies over the landscape, especially in response to management, therefore has long-lasting effects on how productive and resilient the ecosystem will be. In the past, human activity has often accentuated native variability, removing organic matter from sites where it was already in short supply and depositing it in areas of excess. New approaches may now favor the preservation of organic matter both in amount and distribution across the landscape. We know something about how past management has affected organic matter distribution; now, we need to learn how restorative practices will shape its future patterns across the landscape.
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REFERENCES 1. Herrick, J.E.; Wander, M.M. Relationships between soil organic carbon and soil quality in cropped and rangeland soils: the importance of distribution, composition, and soil biological activity. In Soil Processes and the Carbon Cycle; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1997; 405–425. 2. Ajwa, H.A.; Rice, C.W.; Sotomayor, D. Carbon and nitrogen mineralization in tallgrass prairie and agricultural soil profiles. Soil Sci. Soc. Am. J. 1998, 62, 942–951. 3. Zhao, Q.; Zhong, L.; Yingfei, X. Organic carbon storage in soils of southeast China. Nutr. Cycling Agroecosyst. 1997, 49, 229–234. 4. Jobba´gy, E.; Jackson, R.B. The vertical distribution of soil organic carbon and Its relation to climate and vegetation. Ecol. Appl. 2000, 10 (2), 423–436. 5. Paul, E.A.; Follett, R.F.; Leavitt, S.W.; Halvorson, A.; Peterson, G.A.; Lyon, D.J. Radiocarbon dating for determination of soil organic matter pool sizes and dynamics. Soil Sci. Soc. Am. J. 1997, 61, 1058–1067. 6. Trumbore, S. Age of soil organic matter and soil respiration: radiocarbon constraints on belowground C dynamics. Ecol. Appl. 2000, 10 (2), 399–411. 7. Scharpenseel, H.W.; Pfeiffer, E.M.; Becker-Heidmann, P. Ecozone and soil profile screening for C-residence time, rejuvenation, bomb 14C photosynthetic d13C Changes. In Assessment Methods for Soil Carbon; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; Lewis Publishers=CRC Press: Boca Raton, FL, 2001; 207–220. 8. Jenny, H. The Soil Resource: Origin and Behavior; Springer: New York, 1980; 377 pp. 9. Arrouays, D.; Daroussin, J.; Kicin, J.L.; Hassika, P. Improving topsoil carbon storage prediction using a digital elevation model in temperate forest soils of france. Soil Sci. 1998, 163 (2), 103–108. 10. Burke, I.C.; Yonker, C.M.; Parton, W.J.; Cole, C.V.; Flach, K.; Schimel, D.S. Texture, climate, and cultivation effects on soil organic matter content in U.S. grassland soils. Soil Sci. Soc. Am. J. 1989, 53, 800–805. 11. Pennock, D.J. Effects of soil redistribution on soil quality: Pedon, landscape, and regional scales. In Soil Quality for Crop Production and Ecosystem Health; Gregorich, E.G., Carter, M.R., Eds.; Elsevier: Amsterdam, 1997; 167–185. 12. Burke, I.C.; Elliott, E.T.; Cole, C.V. Influence of macroclimate, landscape position, and management on soil organic matter in agroecosystems. Ecol. Appl. 1995, 5 (1), 124–131. 13. Schimel, D.S.; Kelly, E.F.; Yonker, C.; Aguilar, R.; Heil, R.D. Effects of erosional processes on nutrient cycling in Semiarid landscapes. In Planetary Ecology; Caldwell, D.E., Brierley, J.A., Brierley, C.L., Eds.; Van Nostrand Reinhold: New York, 1985; 571–580. 14. Gregorich, E.G.; Greer, K.J.; Anderson, D.W.; Liang, B.C. Carbon distribution and losses: erosion and deposition effects. Soil Till. Res. 1998, 47, 291–302.
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15. Schimel, D.; Stillwell, M.A.; Woodmansee, R.G. Biogeochemistry of C, N, and P in a soil catena of the shortgrass steppe. Ecology 1985, 66 (1), 276–282. 16. Cheng, W.; Virginia, R.A.; Oberbauer, S.F.; Gillespie, C.T.; Reynolds, J.F.; Tenhunen, J.D. Soil nitrogen, microbial biomass, and respiration along an arctic toposequence. Soil Sci. Soc. Am. J. 1998, 62, 654–662. 17. Mueller-Harvey, I.; Juo, A.S.R.; Wild, A. Soil organic C, N, S and P after forest clearance in nigeria: mineralization rates and spatial variability. J. Soil Sci. 1985, 36, 585–591. 18. Tiessen, H.; Santos, M.C.D. Variability of C, N, and P content of a tropical semiarid soil as affected by soil genesis, erosion and land clearing. Plant Soil 1989, 119, 337–341. 19. Chadwick, O.A.; Kelly, E.F.; Merritts, D.M.; Amundson, R.G. Carbon dioxide consumption during soil development. Biogeochemistry 1994, 24, 115–127. 20. Campbell, C.A.; Zentner, R.P.; Selles, F.; Biederbeck, V.O.; McConkey, B.G.; Blomert, B.; Jefferson, P.G. Quantifying short-term effects of crop rotations on soil organic carbon in southwestern saskatchewan. Can. J. Soil Sci. 2000, 80, 193–202. 21. Solomon, D.; Lehmann, J.; Zech, W. Land use effects on soil organic matter properties of chromic luvisols in semiarid Northern Tanzania: carbon, nitrogen, lignin and carbohydrates. Agric. Ecosyst. Environ. 2000, 78, 203–213. 22. Tiessen, H.; Cuevas, E.; Chacon, P. The role of soil organic matter in sustaining soil fertility. Nature 1994, 371, 783–785. 23. Davidson, E.A.; Ackerman, I.L. Changes in coil carbon inventories following cultivation of previously untilled soil. Biogeochemistry 1993, 20, 161–193. 24. Sampson, R.N.; Scholes, R.J. Additional humaninduced activities—article 3.4. In Land Use, Land Use Change, and Forestry. A Special Report of the IPCC; Watson, R.T., Noble, I.R., Bolin, B., Ravindranath, N.H., Verardo, D.J., Dokken, D.J., Eds.; Cambridge University Press: Cambridge, 2000; 180–281. 25. Fernandes, E.C.M.; Motavalli, P.P.; Castilla, C.; Mukurumbira, L. Management control of soil organic matter dynamics in tropical land use systems. Geoderma 1997, 79, 49–67. 26. Franzluebbers, A.J.; Stuedemann, J.A.; Schomberg, H.H. Spatial distribution of soil carbon and nitrogen pools under grazed tall fescue. Soil Sci. Soc. Am. J. 2000, 64, 635–639. 27. Schimel, D.S.; Coleman, D.C.; Horton, K.A. Soil Organic matter dynamics in paired rangeland and cropland toposequences in North Dakota. Geoderma 1985, 36, 201–214. 28. Gregorich, E.G.; Anderson, D.W. Effects of cultivation and erosion on soils of four toposequences in the Canadian prairies. Geoderma 1985, 36, 343–354. 29. Cihacek, L.J.; Ulmer, M.G. Effects of tillage on profile soil carbon distribution in the northern great plains of the U.S. In Management of Carbon Sequestration in Soil; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1997; 83–91.
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30. Mikhailova, E.A.; Bryant, R.B.; Vassenev, I.I.; Schwager, S.J.; Post, C.J. Cultivation effects on soil carbon and nitrogen contents at depth in the Russian chernozem. Soil Sci. Soc. Am. J. 2000, 64, 738–745. 31. Yang, X.-M.; Wander, M.M. Tillage effects on soil organic carbon distribution and storage in a silt loam soil in Illinois. Soil Till. Res. 1999, 52, 1–9. 32. Govers, G.; Lobb, D.A.; Quine, T.A. Tillage erosion and translocation: emergence of a new paradigm in soil erosion research. Soil Till. Res. 1999, 51, 167–174. 33. Meade, R.H.; Yuzyk, T.R.; Day, T.J. Movement and storage of sediment in rivers of the United States and Canada. In The Geology of North America; Wolman, M.G., Riggs, H.C., Eds.; Geological Society of America: Boulder, CO, 1990; Vol. O-1, 255–280. 34. Oldeman, L.R. The global extent of soil degradation. In Soil Resilience and Sustainable Land Use; Greenland, D.J., Szabolcs, I., Eds.; CAB International: Oxfordshire, 1994; 99–118. 35. Pennock, D.J.; De Jong, E. Rates of soil redistribution associated with soil zones and slope classes in Southern Saskatchewan. Can. J. Soil Sci. 1990, 70, 325–334. 36. van Noordwijk, M.; Cerri, C.; Woomer, P.L.; Nugroho, K.; Bernoux, M. Soil carbon dynamics in the humid tropical forest zone. Geoderma 1997, 79, 187–225. 37. Izaurralde, R.C.; Nyborg, M.; Solberg, E.D.; Janzen, H.H.; Arshad, M.A.; Malhi, S.S.; Molina-Ayala, M. Carbon storage in eroded soils after five years of reclamation techniques. In Soil Processes and the Carbon Cycle; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1997; 369–385. 38. Beckett, P.H.T.; Webster, R. Soil variability: a review. Soils Fertil. 1971, 34 (1), 1–15. 39. Starr, G.C.; Lal, R.; Kimble, J.M.; Owens, L. Assessing the impact of erosion on soil organic carbon pools and fluxes. In Assessment Methods for Soil Carbon; Lal, R.,
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Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; Lewis Publishers, CRC Press: Boca Raton, FL, 2001; 417–426. Jacinthe, P.A.; Lal, R.; Kimble, J.M. Assessing water erosion impacts on soil carbon pools and fluxes. In Assessment Methods for Soil Carbon; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; Lewis Publishers, CRC Press: Boca Raton, FL, 2001; 427–449. Bauer, A.; Black, A.L. Quantification of the effect of soil organic matter content on soil productivity. Soil Sci. Soc. Am. J. 1994, 58, 185–193. Beckie, H.J.; Moulin, A.P.; Pennock, D.J. Strategies for variable rate nitrogen fertilization in hummocky terrain. Can. J. Soil Sci. 1997, 77, 589–595. van Kessel, C.; Pennock, D.J.; Farrell, R.E. Seasonal variations in denitrification and nitrous oxide evolution at the landscape scale. Soil Sci. Soc. Am. J. 1993, 57, 988–995. Pennock, D.J.; Corre, M.D. Development and application of landform segmentation procedures. Soil Till. Res. 2001, 58, 151–162. Lal, R.; Bruce, J.P. The potential of world cropland soils to sequester C and mitigate the greenhouse effect. Environ. Sci. Pol. 1999, 2, 177–185. Ellert, B.H.; Janzen, H.H.; McConkey, B.G. Measuring and comparing soil carbon storage. In Assessment Methods for Soil Carbon; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; Lewis Publishers/CRC Press: Boca Raton, FL, 2001; 131–146. Garten, C.T., Jr.; Wullschleger, S.D., Jr. Soil carbon inventories under a bioenergy crop (Switchgrass): measurement limitations. J. Environ. Qual. 1999, 2, 1359–1365. Pennock, D.J.; Frick, A.H. The role of field studies in landscape-scale applications of process models: an example of soil redistribution and soil organic carbon modeling using CENTURY. Soil Till. Res. 2001, 58, 183–191.
Organic Matter Management R. Ce´sar Izaurralde Joint Global Charge Research Institute, College Park, Maryland, U.S.A.
Carlos C. Cerri Universidade de Sa˜o Paulo, CENA, Piracicaba, Sa˜o Paulo, Brazil
INTRODUCTION Soil organic matter (SOM) consists of a complex array of living organisms such as bacteria and fungi, plant and animal debris in different stages of decomposition, and humus—a rather stable brown to black material showing no resemblance to the organisms from which it originates. Because SOM is or has been part of living tissues, its composition is dominated by carbon (C), hydrogen, oxygen and—in lesser abundance—by nitrogen, phosphorus, sulfur among other elements. Levels of SOM are expressed in terms of soil organic carbon (SOC) concentration (g kg1) or mass per unit area (g m2) to a given depth. The level of SOC in virgin soils reflects the action and interaction of the major factors of soil formation: climate, vegetation, topography, parent material, and age. These factors control SOC content by regulating the balance between C gains via photosynthesis and losses via autotrophic and heterotrophic respiration, as well as C losses in soluble and solid form. The SOC content usually ranges between 5 and 100 g kg1 in mineral soils. These concentrations appear modest but at 1500 Pg, the amount of organic C stored globally in soils is second only to that contained in oceans and at least twice that found in either terrestrial vegetation or the atmosphere. Cultivated soils usually contain less SOC than virgin soils[1] due to the magnification of two biophysical processes: 1) net nutrient mineralization accompanied by release of CO2 due to microbial respiration and 2) soil erosion. SOC losses of up to 50% have been reported within 30–70 years of land use conversions under temperate conditions.[2–5] SOC losses reported in subtropical and tropical environments often match or even surpass those observed under temperate conditions.[6–8] In subtropical and tropical environments, shifting cultivation systems appear to conserve more SOC than forestlands permanently cleared for cultivation.[9]
This manuscript has been created by the Battelle Memorial Institute as operator of the Pacific Northwest National Laboratory under Contract No. DE-AC06–76RLO 1830 with the U.S. Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120002260 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
MAJOR PROCESSES LEADING TO CARBON LOSSES FROM SOIL Mineralization Processes Depending on its frequency and kind, tillage changes the soil biophysical environment in ways that affect the net mineralization of nutrients and the release of carbon. These changes can be described in terms of increases or decreases in soil porosity, disruption of soil aggregates, and redistribution in the proportion of soil aggregate size, as well as alteration of energy and water fluxes. All these changes enhance, at least temporarily, the conversion of organic C into CO2[10] and the net release of nutrients from SOM. Much of the success of past agricultural practices relied heavily on the control of decomposition processes through tillage operations to satisfy plant nutrient demands. All this came at a price, however, for a heavy reliance on soil nutrients to feed crops without proper replenishment led to the worldwide declines of SOM.[11] Soil Erosion Processes Agricultural ecosystems normally experience soil losses at rates considerably greater than natural ecosystems because of an incomplete plant or residue cover of the soil during rainy or windy conditions. When surface and environmental conditions are right (i.e., bare soil, sloping land, intense rain, windy weather), the kinetic energy embedded in wind and water is transferred to soil aggregates causing them to be detached and transported away from their original position across fields or downhill. Besides the physical loss of soil particles and on-site impact on soil productivity, the detachment and transport processes also cause aggregate breakdown, thereby exposing labile C to microbial activity. This aggregate breakdown also facilitates the preferential removal of soil materials comprised mainly of humus and clay or silt fractions. Consequently, waterand windborne sediments become enriched in C with respect to the contributing soil. Carbon enrichment ratios ranging from 3 to 360 have been reported.[12,13] The fate of these C-enriched sediments is not well known, 1189
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for while transport and burial of C in eroded sediments may lead to ‘‘sequestration,’’[14] it may also result in part of it being emitted back to the atmosphere as CO2.[15]
Whether or not soil C sequestration practices are widely adopted will depend on their value relative to other C capture and sequestration technologies.
RESTORING SOIL ORGANIC MATTER: THE EMERGING SCIENCE OF SOIL CARBON SEQUESTRATION
Mechanisms of Soil C Sequestration
The Role of Long-Term Field Experiments SOM is an essential attribute of soil quality[16] and has an essential role in soil conservation and sustainable agriculture. Many practices—some involving land use changes—have been shown to increase SOM and thus received considerable attention for their possible role in climate change mitigation.[17–19] Carbon sequestration in managed soils occurs when there is a net removal of atmospheric CO2 because C inputs (nonharvestable net primary productivity) are greater than C outputs (soil respiration, C costs related to fossil fuels and fertilizers). Soil C sequestration has the additional appeal that all its practices conform to principles of sustainable agriculture (e.g., reduced tillage, erosion control, diversified cropping systems, improved soil fertility). Longterm field experiments have been instrumental to increase our understanding of SOM dynamics.[20,21] The first and longest standing experiment was started at Rothamsted, England, by J. B. Lawes and J. H. Gilbert who in 1843 began documenting the impact of nutrient manipulation on crop yields and soil properties.[22] Other experiments were initiated thereafter in America, Europe, and Oceania with the goal of discovering interactions among climate, soil, and management practices. The knowledge that emerged from these experiments has been instrumental for the development and testing of agroecosystem and SOM models.[23]
Recent reviews of experimental results have contributed to organize our understanding of the environmental and management controls of soil C sequestration in grassland[27,28] and agricultural[29,30] ecosystems. The use of C balance, soil fractionation, and isotope techniques have been instrumental to reveal how new C (from crop residues, roots, and organic amendments) enters soil, resides shortly (for a few years) in labile soil fractions, and finally becomes a long-time constituent (for hundreds of years) of recalcitrant organo-mineral complexes.[31] Fig. 1 contrasts young (labile) organic matter fractions extracted from two cultivated soils with and without N fertilizer.[32] The amounts of labile organic matter— fine roots and other organic debris—present in each soil
The Global Importance of Soil C Sequestration There appears to be a significant opportunity for managed ecosystems to act as C sinks. For example, results from inverse modeling experiments suggest that during 1988–1992, terrestrial ecosystems may have been sequestering atmospheric C at rates of 1–2.2 Pg y1.[24] Some of the likely causes include the growth of new forest in previously cultivated land[25] and the ‘‘CO2fertilization effect.’’[26] Globally, agricultural soils have been estimated to have the capacity to sequester C at rates of 0.6 Pg y1[11] during several decades. The realization of this potential C sequestration would not be trivial since it would offset roughly about one-tenth of the current emissions from fossil fuels. In the U.S., annual gains in soil C from improved agricultural practices have been estimated at 0.14 Pg yr1.[25]
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Fig. 1 Young organic matter (fine roots and other organic debris) extracted from two Cryoboralfs under cereal cropping for 13 years receiving N at annual rates of 0 (A) and 50 kg ha1 (B). The black material is charcoal. (From Ref.[32].)
Soil organic carbon (kg m2) Region/country
Climate
Soil
Duration
Crop/land use
Treatment
Initial
Moldboard plow No tillage
Final
Depth (cm)
Reference
4.95 5.46
20
[37]
Argentina
Temperate humid
Argiudoll
17
Corn–wheat–soybean
Chaco, Argentina
Subtropical semiarid
Alfisol
20 10 60
Highly restored Moderately restored Highly degraded
7.05 3.10 1.50
20
[6]
Rondonia, Brazil
Tropical humid
Forest Pasture Pasture Pasture Pasture Pasture
4.33 5.85 5.26 5.28 6.56 6.12
50
[38]
5 9 20 41 81
1.74 2.01 2.00 1.59
6
[39]
30
[40]
4.30 5.00 5.30
15
[35]
2.06 2.22
15
[41]
3.52 3.34 3.22
15
[42]
Georgia, U.S.
Temperate humid
Hapludult
5
Bermudagrass
Unharvested Lightly grazed Heavily grazed Hayed
Kentucky
Temperate humid
Paleudalf
20
Conventional tillage corn
0 kg N=ha1 84 kg N=ha1 168 kg N=ha1 336 kg N=ha1
4.89 5.63 5.64 6.14
No till corn
0 kg N=ha1 84 kg N=ha1 168 kg N=ha1 336 kg N=ha1
5.54 5.84 5.89 6.63
Corn
Conventional Organic Manure
No crops—natural succession
Tillage Control
Cont. wheat Fallow–wheat–wheat Green manure–wheat–wheat
Minimum tillage
Kuztown, Pennsylvania
Temperate humid
Fragiudalf
15
Michigan
Cool temperate humid
Hapludalf
7
Swift Current, Canada
Cold semiarid
Haploboroll
10
1.39
4.20 4.40 4.10
3.05 2.99 2.89
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(Continued)
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Table 1 Examples of worldwide land use and management impacts on SOC
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Table 1 Examples of worldwide land use and management impacts on SOC (Continued) Soil organic carbon (kg m2) Region/country Breton, Canada
Climate Cold subhumid
Soil
Duration
Cryoboralf
51
Russia
Cool temperate humid
Mollisol
300 50 100 50
Punjab, India
Subtropical subhumid
Alluvial
6
Morocco
Warm temperate semiarid
Western Nigeria
Treatment
Wheat–fallow
Nil Fertilizer Manure
Wheat–oat–barley–hay–hay
Nil Fertilizer Manure
Initial
Final
Depth (cm)
Reference
2.64
1.81 2.13 3.11
15
[34]
2.07 2.13 1.59 1.51
50
[5]
0.48
15
[43]
3.73 3.39
20
[44]
2.77 2.96 3.90 1.29
15
[45]
2.91 3.37 4.32
Native grassland Hay Continuous cropping Continuous fallow Corn–wheat
11
Continuous wheat and other rotations
20 25 10 10
Bush fallow Bush fallow Bermudagrass Cultivation
Minimum tillage, residue retained Minimum tillage, residue removed Conventional tillage Conventional tillage No tillage
0.48 0.50 3.20
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Calcixeroll
Crop/land use
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reflect differences in crop productivity induced by addition of N at annual rates of 50 kg ha1 for 13 years. ‘Terra Preta’ soil—in tropical regions of South America and West Africa—represents a prime example of ancient wisdom applied to develop sustainable agriculture through the improvement of soil fertility and SOM.[33] The quantity and quality of C entering soil as well as the interaction of this C with the soil biophysical environment are major factors determining the rate and duration of soil C sequestration. The quantity of C added to soil in the form of roots, crop residues, and organic amendments has been shown to play a dominant role in defining the trajectory of SOC over time.[34] Management practices geared toward optimizing nutrient supply and building nutrient reserves (e.g., fertilization, use of legumes in crop rotations) are almost guaranteed to increase soil C stocks. The quality of crop residues and the timing of their incorporation to soil also have an influential role on C decomposition and, thus, on soil C storage.[35] The degree of soil disturbance—through its impact on soil aggregation—constitutes another major factor regulating C decomposition and retention in soil.[36] In this context, no tillage agriculture has come to represent one of the most significant technological innovations of the last 30 years because it allows farmers the possibility of growing crops economically while reducing erosion and improving both quantity and quality of SOM. A few examples of the management impacts on soil C sequestration from around the world are presented in Table 1. Soil Organic Matter, Energy, and Full C Accounting Land is the natural habitat of humans. Humans dwell on it and use it as a resource for the production of food, fiber, and other goods. Simply put, land is managed when there is a manipulation of energy and matter flows in order to meet certain economic and social objectives. Farm mechanization and fertilizers are two of the many technical innovations that—though they rely on the utilization of fossil energy—have brought dramatic increases in food production during the last century. Changes in management practices that include soil C sequestration as an objective require careful evaluation of their impact not only on soil C gains but also on C costs from the use of fossil energy (e.g., manufacture of fertilizers)[46,47] and on the net greenhouse gas emissions.[48]
THE ROLE OF SOIL ORGANIC MATTER IN THE 21ST CENTURY SOM has played and will continue to play a central role in sustainable land management. The restoration of
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SOM at global scales offers a unique opportunity to mitigate global warming. As population levels and affluence increase, demands on land to produce food, fiber, biomass, and other products will remain high. Because land is finite, important decisions will have to be made in order to balance such demands with functional objectives such as the preservation of natural ecosystems. As part of any climate policy, the impact of land use changes and management on SOM storage should be included as a criterion for making these decisions. Depending on their degree of expansion, several evolving agricultural technologies—such as genetically modified crops, conservation tillage, organic farming, and precision farming—may have important implications for soil C sequestration.[19] Their ultimate impact on C sequestration will depend not only on the economic benefit realized by individual producers but also on whether society recognizes the value of soil C storage to mitigate global warming.
REFERENCES 1. Davidson, E.A.; Ackerman, I.L. Changes in soil carbon following cultivation of previously untilled soils. Biogeochemistry 1993, 20, 161–164. 2. Dalal, R.C.; Mayer, R.J. Long-term trends in fertility of soils under continuous cultivation and cereal cropping in southern Queensland. II. Total organic carbon and its rate of loss from the soil profile. Aust. J. Soil Res. 1986, 24, 281–292. 3. Mann, L.K. Changes in soil carbon after cultivation. Soil Sci. 1986, 142, 279–288. 4. Ellert, B.H.; Gregorich, E.G. Storage of carbon, nitrogen and phosphorus in cultivated and adjacent forested soils of Ontario. Soil Sci. 1996, 161, 587–603. 5. Mikhailova, E.A.; Bryant, R.B.; Vassenev, I.I.; Schwager, S.J.; Post, C.J. Cultivation effects on soil carbon and nitrogen contents at depth in the Russian chernozem. Soil Sci. Soc. Am. J. 2000, 64, 738–745. 6. Abril, A.; Bucher, E.H. Overgrazing and soil carbon dynamics in the western chaco of Argentina. Appl. Soil Ecol. 2001, 16, 243–249. 7. Lal, R. Deforestation and land use effects on soil degradation and rehabilitation in western Nigeria, II. Soil chemical properties. Land Degrad. Dev. 1996, 7, 87–98. 8. Lobe, I.; Amelung, W.; Du Preez, C.C. Losses of carbon and nitrogen with prolonged arable cropping from sandy soils of the South African highveld. Eur. J. Soil Sci. 2001, 52, 93–101. 9. Houghton, R.A. Changes in the storage of terrestrial carbon since 1850. In Soils and Global Change; Lal, R., Kimble, J., Levine, E., Stewart, B.A., Eds.; CRC= Lewis Publishers: Boca Raton, FL, 1995; 45–65. 10. Reicoski, D.C.; Lindstrom, M.J. Fall tillage method: effect from short-term carbon dioxide flux from soil. Agron. J. 1993, 85, 1237–1243.
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11. Cole, V.; Cerri, C.; Minami, K.; Mosier, A.; Rosenberg, N.J.; Sauerbeck, D. Agricultural options for mitigation of greenhouse gas emissions. In Climate Change 1995: Impacts, Adaptations and Mitigation of Climate Change; Watson, R.T., Zinowera, M.C., Moss, R.H., Eds.; Report of IPCC Working Group II; Cambridge University Press: London, UK, 1996; 745–771. 12. Sterk, G.; Herrmann, L.; Bationo, A. Wind-blown nutrient transport and soil productivity changes in southwest Niger. Land Degrad. Dev. 1996, 7, 325–336. 13. Zobeck, T.M.; Fryrear, D.W. Chemical and physical characteristics of wind-blown sediment. Trans. Am. Soc. Agric. Eng. 1986, 29, 1037–1041. 14. Stallard, R.F. Terrestrial sedimentation and the carbon cycle: coupling weathering and erosion to carbon burial. Global Biogeochem. Cycles 1998, 12, 231–257. 15. Lal, R. Global soil erosion by water and C dynamics. In Soils and Global Change; Lal, R., Kimble, J., Levine, E., Stewart, B.A., Eds.; CRC=Lewis Publishers: Boca Raton, FL, 1995; 131–141. 16. Doran, J.W., Coleman, D.C., Bezdicek, D.F., Stewart, B.A., Eds.; Defining Soil Quality for a Sustainable Environment; Soil Science Society America Special Publication No. 35; SSSA: Madison, WI, 1994; 244 pp. 17. Batjes, N.H. Mitigation of atmospheric CO2 concentrations by increased carbon sequestration in the soil. Biol. Fert. Soils 1998, 27, 230–235. 18. Post, W.M.; Kwon, K.C. Soil carbon sequestration and land-use change: processes and potential. Global Change Biol. 2000, 6, 317–327. 19. Izaurralde, R.C.; Rosenberg, N.J.; Lal, R. Mitigation of climatic change by soil carbon sequestration: issues of science, monitoring and degraded lands. Adv. Agron. 2001, 70, 1–75. 20. Powlson, D.S., Smith, P., Smith, J.U., Eds.; Evaluation of Soil Organic Matter Models Using Existing Long-Term Datasets; NATO ASI Series I; Springer: Heidelberg, 1996; Vol. 38, 429 pp. 21. Paul, E.A., Paustian, K., Elliott, E.T., Cole, C.V., Eds.; Soil Organic Matter in Temperate Agroecosystems: Long-Term Experiments in North America; NATO ASI Series I; CRC=Lewis Publishers: Boca Raton, FL, 1997; 414 pp. 22. Jenkinson, D.S. The rothamsted long-term experiments: are they still of use? Agron. J. 1991, 83, 2–10. 23. Smith, P.; Smith, J.U.; Powlson, D.S.; McGill, W.B.; Arah, J.R.M.; Chertov, O.; Coleman, K.W.; Franko, U.; Frolking, S.; Jenkinson, D.S.; Jensen, L.S.; Kelly, R.H.; Klein-Gunnewiek, H.; Komarov, A.S.; Li, C.; Molina, J.A.E.; Mueller, T.; Parton, W.J.; Thornley, J.H.M.; Whitmore, A.P. A comparison of the performance of nine soil organic matter models using datasets from seven long-term experiments. Geoderma 1997, 81, 153–225. 24. Fan, S.; Gloor, M.; Mahlman, J.; Pacala, S.; Sarmiento, J.; Takahashi, T.; Tans, P. A large terrestrial carbon sink in North America implied by atmospheric and oceanic carbon dioxide data and models. Science 1998, 282, 442–446. 25. Houghton, R.A.; Hackler, J.L.; Lawrence, K.T. The U.S. carbon budget: contributions from land use change. Science 1999, 285, 574–578.
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26. Kimball, B.A. Carbon dioxide and agricultural yield: an assemblage and analysis of 430 prior observations. Agron. J. 1983, 75, 779–782. 27. Conant, R.T.; Paustian, K.; Elliott, E.T. Grassland management and conversion into grassland: effects on soil carbon. Ecol. Appl. 2001, 11, 343–355. 28. Scott, N.A.; Tate, K.R.; Ford-Robertson, J.; Giltrap, D.J.; Smith, C.T. Soil carbon storage in plantations and pastures: land-use implications. Tellus 1999, 51B, 326–335. 29. Janzen, H.H.; Campbell, C.A.; Izaurralde, R.C.; Ellert, B.H.; Juma, N.; McGill, W.B.; Zentner, R.P. Management effects on soil c storage on the Canadian prairies. Soil Till. Res. 1998, 47, 181–195. 30. Paustian, K.; Collins, H.P.; Paul, E.A. Management controls on soil carbon. In Soil Organic Matter in Temperate Ecosystems: Long-Term Experiments in North America; Paul, E.A., Paustian, K., Elliott, E.T., Cole, C.V., Eds.; CRC=Lewis Publishers: Boca Raton, FL, 1997; 15–49. 31. Jastrow, J.D. Soil aggregate formation and the accrual of particulate and mineral-associated organic matter. Soil Biol. Biochem. 1996, 28, 665–676. 32. Solberg, E.D.; Nyborg, M.; Izaurralde, R.C.; Malhi, S.S.; Janzen, H.H.; Molina-Ayala, M. Carbon storage in soils under continuous cereal grain cropping: N fertilizer and straw. In Management of Carbon Sequestration in Soil; Lal, R., Kimble, J., Follett, R., Stewart, B.A., Eds.; CRC/Lewis Publishers: Boca Raton, FL, 1998; 235–254. 33. Glaser, B.; Haumaier, L.; Guggenberger, G.; Zech, W. The ‘‘Terra Preta’’ phenomenon: a model for sustainable agriculture in the humid tropics. Naturwissenschaften 2001, 88, 37–41. 34. Izaurralde, R.C.; McGill, W.B.; Robertson, J.A.; Juma, N.G.; Thurston, J.T. Carbon balance of the breton classical plots after half a century. Soil Sci. Soc. Am. J. 2001, 65, 431–441. 35. Drinkwater, L.E.; Wagoner, P.; Sarrantonio, M. Legume-based cropping systems have reduced carbon and nitrogen losses. Nature 1998, 396, 262–265. 36. Six, J.; Elliott, E.T.; Paustian, K. Soil macroaggregate turnover and microaggregate formation: a mechanism for C sequestration under no-tillage agriculture. Soil Biol. Biochem. 2000, 32, 2099–2103. 37. Alvarez, R.; Russo, M.E.; Prystupa, P.; Scheiner, J.D.; Blotta, L. Soil carbon pools under conventional and no-tillage systems in the argentine rolling pampa. Agron. J. 1998, 90, 138–143. 38. Neill, C.; Cerri, C.C.; Melillo, J.M.; Feigl, B.J.; Steudler, P.A.; Moraes, J.F.L.; Piccolo, M.C. Stocks and dynamics of soil carbon following deforestation for pasˆ nia. In Soil Processes and the Carbon ture in Rondo Cycle; Lal, R., Kimble, J., Follett, R., Stewart, B.A., Eds.; CRC=Lewis Publishers: Boca Raton, FL, 1998; 9–28. 39. Franzluebbers, A.J.; Stuedemann, J.A.; Wilkinson, S.R. Bermudagrass management in the southern piedmont USA: I. Soil and surface residue carbon and sulfur. Soil Sci. Soc. Am. J. 2001, 65, 834–841.
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40. Ismail, I.; Blevins, R.L.; Frye, W.W. Long-term notillage effects on soil properties and continuous corn yields. Soil Sci. Soc. Am. J. 1994, 58, 193–198. 41. Richter, D.D.; Babbar, L.I.; Huston, M.A.; Jaeger, M. Effects of annual tillage on organic carbon in a finetextured udalf: the importance of root dynamics to soil carbon storage. Soil Sci. 1999, 149, 78–83. 42. Curtin, D.; Wang, H.; Selles, F.; McConkey, B.G.; Campbell, C.A. Tillage effects on carbon fluxes in continuous wheat and fallow–wheat rotations. Soil Sci. Soc. Am. J. 2000, 64, 2080–2086. 43. Ghuman, B.S.; Sur, H.S. Tillage and residue management effects on soil properties and yields of rainfed maize and wheat in a subhumid subtropical climate. Soil Till. Res. 2001, 58, 1–10. 44. Mrabet, R.; Saber, N.; El-Brahli, A.; Lahlou, S.; Bessam, F. Total, particular organic matter and
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structural stability of a calcixeroll soil under different wheat rotations and tillage systems in a semiarid area of Morocco. Soil Till. Res. 2001, 57, 225–235. Lal, R. Land use and soil management effects on soil organic matter dynamics on alfisols in western Nigeria. In Soil Processes and the Carbon Cycle; Lal, R., Kimble, J., Follett, R., Stewart, B.A., Eds.; CRC/Lewis Publishers: Boca Raton, FL, 1998; 109–126. Schlesinger, W.H. Carbon and agriculture: carbon sequestration in soils. Science 1999, 284, 2095. Izaurralde, R.C.; McGill, W.B.; Rosenberg, N.J. Carbon cost of applying nitrogen fertilizer. Science 2000, 288, 811–812. Robertson, G.P.; Paul, E.A.; Harwood, R.R. Greenhouse gases in intensive agriculture: contributions of individual gases to the radiative forcing of the atmosphere. Science 2000, 289, 1922–1925.
Organic Matter Modeling Peter Smith School of Biological Sciences, University of Aberdeen, Aberdeen, U.K.
INTRODUCTION There are a number of approaches to modeling soil organic matter (SOM) turnover including 1) processbased multicompartment models; 2) models that consider each fresh addition of plant debris as a separate cohort which decays in a continuous way; and 3) models that account for C and N transfers through various trophic levels in a soil food web. These approaches are described in more detail below.
PROCESS-BASED, MULTICOMPARTMENT SOM MODELS Most models are process-based, i.e., they focus on the processes mediating the movement and transformations of matter or energy and usually assume first order rate kinetics.[1] Early models simulated the SOM as one homogeneous compartment.[2] Some years later two-compartment models were proposed[3,4] and, as computers became more accessible, multicompartment models were developed.[5,6] Of the 33 SOM models currently represented within the Global Change and Terrestrial Ecosystems (GCTE) Soil Organic Matter Network (SOMNET) database,[7–9] 30 are multicompartment, process-based models. Each compartment or SOM pool within a model is characterized by its position in the model’s structure and its decay rate. Decay rates are usually expressed by first-order kinetics with respect to the concentration (C) of the pool dC=dt ¼ kC where t is the time. The rate constant k of first-order kinetics is related to the time required to reduce by half the concentration of the pool ‘‘when there is no input.’’ The pool’s half-life [h ¼ (ln 2)=k], or its turnover time (t ¼ 1=k) are sometimes used instead of k to characterize a pool’s dynamics: the lower the decay rate constant, the higher the half-life, the turnover time, and the stability of the organic pool. The flows of C within most models represent a sequence of carbon going from plant and animal debris to the microbial biomass, and then to soil organic pools of increasing stability. Some models also use 1196 Copyright © 2006 by Taylor & Francis
feedback loops to account for catabolic and anabolic processes and microbial successions. The output flow from an organic pool is usually split. It is directed to a microbial biomass pool, another organic pool, and, under aerobic conditions, to CO2. This split simulates the simultaneous anabolic and catabolic activities and growth of a microbial population feeding on one substrate. Two parameters are required to quantify the split flow. They are often defined by a microbial (utilization) efficiency and stabilization (humification) factor which control the flow of decayed C to the biomass and humus pools, respectively. The sum of the efficiency and humification factors must be inferior to one to account for the release of CO2. A thorough review of the structure and underlying assumptions of different process-based SOM models is available.[6]
COHORT MODELS DESCRIBING DECOMPOSITION AS A CONTINUUM Another approach in modeling SOM turnover is to treat each fresh addition of plant debris into the soil as a cohort.[5] Such models consider one SOM pool that decays with a feedback loop into itself. For example, Q-SOIL[10] is represented by a single rate equation. The SOM pool is divided into an infinite number of components, each characterized by its ‘‘quality’’ with respect to degradability as well as impact on the physiology of the decomposers. The rate equation for the model Q-SOIL represents the dynamics of each SOM component of quality q and is quality dependent. Exact solutions to the rate equations are obtained analytically.[11]
FOOD-WEB MODELS Another type of model simulates C and N transfers through a food web of soil organisms;[1,12] such models explicitly account for different trophic levels or functional groups of biota in the soil.[13–18] Some models that combine an explicit description of the soil biota with a process-based approach have been developed.[19] Food-web models require a detailed knowledge of the Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042721 Copyright # 2006 by Taylor & Francis. All rights reserved.
Organic Matter Modeling
biology of the system to be simulated and are usually parameterized for application at specific sites.
FACTORS AFFECTING SOM TURNOVER IN MODELS Rate ‘‘constants’’ (k) are constant for a given set of biotic and abiotic conditions. For nonoptimum environmental circumstances, the simplest way to modify the maximum value of k is by multiplication by a reduction factor m—ranging from 0 to 1. Environmental factors considered by SOM models include temperature, water, pH, nitrogen, oxygen, clay content, cation exchange capacity, type of crop=plant cover, and tillage. Many studies show the effect of temperature on microbially mediated transformations in soil, either expressed as a reduction factor or the Arrhenius equation; but the assumption that SOM decomposition is temperature dependent has been challenged by a study suggesting that old SOM in forest soils does not decompose more rapidly in soils from warmer climates than in soils from colder regions.[20] Recent studies, however, suggest that old SOM is not more resistant than younger pools of SOM.[21,22] Water and oxygen have a major impact on the microbial physiology. Whilst some models simulate O2 concentrations in soil explicitly,[23,24] many define the extent of anaerobiosis based on soil pore space filled with water (WFPS).[25,26] Soil clay content and total SOM are correlated. Various schemes simulate the effect of clay on rate equations to obtain SOM accumulation. Nitrogen is an essential element for microbial growth that will be maximal when enough N is assimilated to maintain the microbial C : N ratio.[27] An overview of the 33 models represented in the GCTE-SOMNET[7,8] including the factors affecting SOM turnover are presented in Table 1.
SOM MODEL EVALUATION There are many reasons for evaluating the performance of a SOM model. Model evaluation shows how well a model can be expected to perform in a given situation, it can help to improve the understanding of the system (especially where the model fails), it can provide confidence in the model’s ability to predict changes in SOM in the future or where there are no data, and it can be used to assess the uncertainties associated with the model’s predictions. Models can be evaluated at a number of different levels. They can be evaluated at the individual process level, at the level of a subset of processes (e.g., net mineralization), or the model’s overall outputs (e.g., changes in total SOM over time) can be tested against measured
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laboratory and field data. Models can also be evaluated for their applicability in different situations, e.g., for scaling-up simulated net C storage from a site specific to a regional level.[61] Many examples of different forms of SOM model evaluation are presented elsewhere.[6] In the most comprehensive evaluation of SOM models to date,[61] nine models were tested against 12 data sets from seven long-term experiments representing arable rotations, managed and unmanaged grassland, forest plantations, and natural woodland regeneration. The results showed that six models had significantly lower overall errors [root mean square error (RMSE)] than another group of three models (Fig. 1). The poorer performance of three of the models was related to failures in other parts of the ecosystem models, thus providing erroneous inputs into the SOM module.[61]
SOM MODEL APPLICATION Soil organic matter models are often used as research tools in that they are hypotheses of the dynamics of C and N in soil and can be used to distinguish between competing hypotheses.[49] Another increasing application of SOM models is in agronomy; many SOM models are now being used to improve agronomic efficiency and environmental quality through incorporation into decision support systems, e.g., SUNDIAL-FRS,[56] DSSAT,[35] and APSIM.[29] Soil organic matter models are now used, more than ever, to extrapolate our understanding of SOM dynamics both temporally (in to the future) and spatially (to assess C fluxes from whole regions or continents). An early example of a regional scale application was the use of the CENTURY model to predict the effects of alternative management practices and policies in agroecosystems of central U.S.[63] Since then, many studies have adopted similar methodologies to assess SOM dynamics at the regional,[64] national,[65,66] and global scales.[67–75] Soil organic matter models are increasingly being used by policy makers at the national, regional, or global scales, for example, in the postKyoto debate on the ability of the terrestrial biosphere to store carbon.[76] With such an important role in society, it is important that SOM models are transparent, well evaluated, and well documented. There is still a variety of understanding and different hypotheses incorporated in our current SOM models. Future developments in SOM models will further improve our understanding and allow models to be used truly predictively, without the need for site-specific calibration. These developments will improve estimates of, and reduce, the uncertainty associated with SOM model predictions.
1198
Table 1 Overview of SOM models represented within GCTE-SOMNET in January 2001 Inputs Model
Factors affecting decay rate constants
Meteorology
Soil and plant
Management
ANIMO
Day, week, month
P, AT, Ir, EvW
Des, Lay, Imp, Cl, OM, N, pH
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, pH, N, O
C, N, W, ST, gas
[28]
APSIM
Day
P, AT, Ir
Lay, W, C, N, BD, Wi, PG, PS
Rot, Ti, Fert, Irr
T, W, pH, N
C, N, W, ST, gas
[29]
Candy
Day
P, AT, Ir
D, Imp, W, N, C, Wi, PD, Nup
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N, Cl
C, N, W, ST, gas
[30]
CENTURY
Month
P, AT
W, Cl, OM, pH, C, N
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N, Cl, pH, Ti
C, BioC, 13C, 14C, N, W, ST, gas
[31]
Chenfang Lin Model
Day
ST
OM, BD, W
Man, Res
T, W, F
C, BioC, gas
[32]
DAISY
Hour, day
P, AT, Ir, EvG
Lay, Cl, C, N, PG, PS
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N, Cl
C, BioC, N, W, ST, gas
[33]
DNDC
Hour, day, month
P, AT
Lay, Cl, OM, pH, BD
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N, Cl, Ti
C, BioC, N, W, ST, gas
[34]
DSSAT
Hour, day, month, year
P, AT, Ir
Des, Lay, Imp, W, Cl, PS, OM, pH, C, N
Rot, Ti, Fert, Man, Res, Irr
T, W, N, Cl, Ti
C, BioC, N, W, ST
[35]
D3R
Day
P, AT
Y, PS
Rot, Ti, Res
T, W, N, Cv, Ti
Decomp. of surface and buried residue
[36]
Ecosys
Minute, hour
P, AT, Ir, WS, RH
Lay, W, Cl, CEC, PS, OM, pH, N, BD, PG, PS
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N, O, Cl, Cv
C, BioC, N, W, ST, pH, Ph, EC, gas, ExCat
[37]
EPIC
Day
P, AT
Lay, Imp, W, Cl, OM, pH, C, BD, Wi
Rot, Ti, Fert, Man, Res, Irr,AtN
T, W, N, pH, Cl, Ce, Cv
C, BioC, N, W, ST
[38]
FERT
Day
P, AT, WS
Des, Lay, W, Cl, OM, pH, C, N, BD, W, Ph, K, Nup, Y, PS
Rot, Ti, Fert, Man, Res, Irr
T, W, N, pH, Cv
C, N, Ph, K
[39]
ForClim-D
Year
P, AT
W, AG
None
T, W
C
[40]
GENDEC
Day, month
ST, W
W, InertC, LQ
Can be used—not essential
T, W, N
C, BioC, N, gas, LQ
[41]
HPM=EFM
Day
P, AT, Ir, WS
W, Cl, PS
Rot, Fert, Irr, AtN
T, W, N
C, BioC, N, W, gas
[42]
ICBM
Day, year
Combination of weather & climate
Many desirable: none essential
C inputs to soil
T, W, Cl
C
[43]
KLIMATSOIL-YIELD
Day, year
P, AT, ST, Ir, EvG, EvS, VPD, SH
Des, Lay, Imp, W, Cl, PS, OM, pH, C, N
Fert, Man, Res, Irr
T, W, N, Cl
C, BioC, N, W, ST
[44]
Copyright © 2006 by Taylor & Francis
Soil outputs
References
Organic Matter Modeling
Timestep
Day
P, AT, Ir
Lay, Inp, W, Cl, CEC, OM, pH, C, N, PS, AS
Fert
T, W, N, pH
C, N, W, ST
[45]
Humus balance
Year
Climate based on P and AT
Des, Lay, PS, OM, pH, C, N
Rot, Fert, Man
N, H, Cl, Cv
C, N
[46]
MOTOR
User specified
P, AT, EvG
Des, OM
Rot, Ti, Fert, Man
T, W, N, Cl, Ti
C, BioC, 13C, 14C, gas
[47]
NAM SOM
Year
P, AT
Des, PS, OM, Ero
Man, Res
T, W, Cl, Cv
C, BioC
[48]
NCSOIL
Day
ST (P, AT)
W, OM, C, N
Fert, Man, Res
T, W, N, pH, Cl, Ti
C, BioC, 14C, N, 15N, gas
[49]
NICCE
Hour, day
P, AT, Ir, WS
Imp, OM, C, N, W, TC, PG
Fert, Man, Res, Irr, AtN
T, W, Cl, N
C, BioC, 13C, 14C, N, 15N, W, ST, gas
[50]
O’Brien model
Year
None
Lay, C, 14C
None
None
C, 14C
[51]
O’Leary model
Day
P, AT
Lay, W, Cl, pH, N
Ti, Fert, Res
T, W, N, Cl, Ti
C, BioC, N, W, ST, gas, ResC, ResN
[52]
Q-soil
Year
Optional
C, N
Rot, Fert, Man, Res, AtN
T, W, N
C, BioC, 13C, N
[10]
RothC
Month
P, AT, EvW
Cl, C, InertC (can be estimated)
Man, Res, Irr
T, W, Cl, Cv
C, BioC, gas, 14C
[53]
SOCRATES
Week
P, AT
CEC, Y
Rot, Fert, Res
T, W, N, Cv, Ce
C, BioC, gas
[54]
SOMM
Day
P, ST
OM, N, AshL, NL
Man
T, W, N
C, N, gas
[55]
Sundial
Week
P, AT, EvG
Imp, Cl, W, Y
Rot, Fert, Man, Res, Irr, AtN
T, W, N, Cl
C, BioC, N, 15N, W, gas
[56]
Verberne
Day
P, AT, Ir, WS, EvS
Des, W, Cl, PS, OM, C, N
Man, AtN
T, W, N, Cl
C, BioC, N, W
[57]
VOYONS
Day, week, month
P, ST
Cl, OM, C, N
Fert, Man, Res, Irr, AtN
T, W, Cl
C, BioC, 13C, 14C, N, gas
[58]
Wave
Day
P, AT, Ir, EvG
Lay, OM, C, N, W, PG
Rot, Ti, Fert, Man, Res, Irr, AtN
T, W, N
C, N, W, ST, gas
[59]
Organic Matter Modeling
CNSP pasture model
P, precipitation; AT, air temperature; ST, soil temperature; Ir, irradiation; EvW, evaporation over water; EvG, evaporation over grass; EvS, evaporation over bare soil; WS, wind speed; RH, relative humidity; VPD, vapor pressure deficit; SH, sun hours; Des, soil description; Lay, soil layers; Imp, depth of impermeable layer; Cl, clay content; OM, organic matter content; N, soil nitrogen content= dynamics; C, soil carbon content= dymanics; InertC, soil inert carbon content; W, Soil water characteristics; Wi, wilting point; PD, soil particle size distribution; CEC, cation exchange capacity; Ero, annual erosion losses; BD, soil bulk density; TC, thermal conductivity; PG, plant growth characteristics; PS, plant species composition; AS, animal species present; AG, animal growth characteristics; Y, yield; Nup, plant nitrogen uptake; LQ, litter quality; AshL, ash content of litter; NL, N content of litter; Rot, rotation; Ti, tillage practice; Fert, inorganic fertilizer applications; Man, organic manure applications; Res, residue management; Irr, irrigation; AtN, atmospheric nitrogen inputs; T, temperature; W, water; N, nitrogen; O, oxygen; Cl, clay; Ce, cation exchange capacity; Cv, cover crop; Ti, tillage; F, Fauna; BioC, Biomass carbon; 13C, 13C dynamics; 14C, 14C dynamics; 15N, 15N dynamics; gas, gaseous losses (e.g., CO2, N2O, and N2); ResC, surface residue carbon; ResN, surface residue nitrogen; Ph, phosphorus dynamics; K, potassium dynamics; EC, electrical conductivity; ExCat, exchangeable cations. NB, N in the soil inputs and outputs section is used to denote all aspects of the N cycle. Further details regarding optimum decay conditions, SOM components, rate constants, methods of pool fitting, and refractory SOM are given elsewhere. (Refs.[6,60] and a metadatabase of all models is available Ref.[7].) 1199
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1200
Fig. 1 Overall root mean square error value for nine SOM models when simulating changes in total soil organic carbon in up to 12 datasets from seven long term experiments. The RMSE values of the models with the same letter (a or b) do not differ significantly (two sample, two tailed t-test; p > 0.05), but the RMSE values of the two groups (a and b) do differ significantly (two sample, two tailed t-test; p < 0.05).[62]
CONCLUSIONS Soil organic matter models are used for many purposes in soil science, including use as tools to synthesize and explore, explain, and extrapolate experimental data, use for making projections of SOM behavior under current and future environmental conditions, and use for supporting decision making at many levels, by many users. Soil organic matter models remain one of our most important tools for improving our understanding soil of organic matter dynamics.
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Organic Matter Modeling
65. Lee, J.J.; Phillips, D.L.; Liu, R. The effect of trends in tillage practices on erosion and carbon content of soils in the US corn belt. Water Air Soil Poll. 1993, 70, 389–401. 66. Parshotam, A.; Tate, K.R.; Giltrap, D.J. Potential effects of climate and land-use change on soil carbon and CO2 emissions from New Zealand’s indigenous forests and unimproved grasslands. Weather Climate 1996, 15, 3–12. 67. Post, W.M.; Emanuel, W.R.; Zinke, P.J.; Stangenberger, A.G. Soil carbon pools and world life zones. Nature 1982, 298, 156–159. 68. Post, W.M.; Pastor, J.; Zinke, P.J.; Staggenberger, A.G. Global patterns of soil nitrogen storage. Nature 1985, 317, 613–616. 69. Post, W.M.; King, A.W.; Wullschleger, S.D. Soil organic matter models and global estimates of soil organic carbon. In Evaluation of Soil Organic Matter Models Using Existing, Long-Term Datasets; Powlson, D.S., Smith, P., Smith, J.U., Eds.; NATO ASI I38; Springer-Verlag: Berlin, 1996; 201–222. 70. Potter, C.S.; Randerson, J.T.; Field, C.B.; Matson, P.A.; Vitousek, P.M.; Mooney, H.A.; Klooster, S.A. Terrestrial ecosystem production: a process model based on satellite and surface data. Global Biogeochem. Cycles 1993, 7, 811–841. 71. Schimel, D.S.; Braswell, B.H., Jr.; Holland, E.A.; McKeown, R.; Ojima, D.S.; Painter, T.H.; Parton, W.J.; Townsend, J.R. Climatic, edaphic, and biotic controls over storage and turnover of carbon in soils. Global Biogeochem. Cycles 1994, 8, 279–293. 72. Goto, N.; Sakoda, A.; Suzuki, M. Modelling soil carbon dynamics as a part of the carbon cycle in terrestrial ecosystems. Ecol. Model. 1993, 74, 183–204. 73. Esser, G. Modelling global terrestrial sources and sinks of CO2 with special reference to soil organic matter. In Soils and the Greenhouse Effect; Bouwman, A.F., Ed.; John Wiley & Sons: NewYork, 1990; 247–261. 74. Goldewijk, K.K.; van Minnen, J.G.; Kreileman, G.J.J.; Vloedbeld, M.; Leemans, R. Simulating the carbon flux between the terrestrial environment and the atmosphere. Water Air Soil Poll. 1994, 76, 199–230. 75. Melillo, J.M.; Kicklighter, D.W.; McGuire, A.D.; Peterjon, W.T.; Newkirk, K.M. Global change and its effect on soil organic carbon stocks. In Role of Nonliving Organic Matter in the Earth’s Carbon Cycle; Zepp, R.G., Sonntag, C.H., Eds.; John Wiley & Sons: New York, 1995; 175–189. 76. IPCC. Land Use, Land-Use Change, and Forestry. A Special Report of the IPCC; Cambridge University Press: Cambridge, U.K., 2000; 377 pp.
Organic Matter Structure and Characterization Georg Guggenberger Institute of Soil Science and Soil Geography, University of Bayreuth, Bayreuth, Germany
INTRODUCTION Soil organic matter (SOM) encompasses all biologicallyderived organic material found in the soil or on its surface irrespective of 1) source; 2) whether it is living or dead; or 3) stage of decomposition, but excluding the aboveground portion of living plants.[1] This implies large structural heterogeneity and close linkage to SOM functions. Litter composition and its changes during biotic and abiotic transformation are key variables in the processes and the size of carbon sequestration in soil. In the context of the Kyoto Protocol, analysis of SOM structure helps us to understand these processes and to predict changes in the sign and magnitude of terrestrial carbon fluxes in a changing environment. To reduce SOM heterogeneity, different components of SOM need to be separated into entities that differ in terms of source, composition, and turnover. Recent evidence suggests that the classical chemical fractionation into fulvic acids, humic acids, and humin according to solubility characteristics in dilute acid and base (for standard procedure see Ref.[2]) is not useful in this respect.[3] Fractionations that are more promising rely mostly on physical fractionations according to particle size or density,[4,5] and the analysis of dissolved organic matter in the soil solution.[6] ANALYTICAL METHODS The analytical approaches can be divided into degradative methods involving chemolysis, thermolysis, or thermochemolysis, and noninvasive spectroscopic techniques such as nuclear magnetic resonance (NMR) spectroscopy (Table 1). Degradative methods provide molecular-level information on specific organic compounds accessible to the degradative step whereas spectroscopic techniques inform on the bulk composition of SOM. Since all analytical approaches have their drawbacks, a comprehensive picture of the SOM structure can only be obtained using a combination of various methods.[7] Degradative Methods Chemolysis of SOM involves various degradation procedures (hydrolysis, oxidation, extraction) that are Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001588 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
selective in their attack on specific molecular structures (Table 1). The techniques are well suited to follow the often subtle changes in the composition of plant- and microbial-derived biopolymers during microbial transformation processes, in particular when different soil fractions are comparatively investigated.[8,9] But only a part of SOM present in specific structures—as determined by NMR spectroscopy—can be identified with these techniques, and information on the original macromolecular structure of SOM is limited.[10] Analytical pyrolysis uses thermal degradation to cleave bonds in the organic macromolecules and enables a sensitive and rapid characterization of organic constituents.[11] Problems may arise due to the complicated pyrolysis behavior of many organic compounds, in particular in the presence of catalytic minerals. Thermal secondary reaction causes considerable modification of the organic compound, which may bias the interpretation of the pyrolysis products with respect to their mother compounds.[12,13] Some of the problems can be solved by thermochemolysis utilizing tetramethylammonium hydroxide (TMAH).[13,14] Hydroxyl and carboxyl groups are converted into their respective methyl ethers and methyl esters to avoid fragmentation of aliphatic and benzenecarboxylic acids. Spectroscopic Techniques Nuclear magnetic resonance spectroscopy has a large potential to analyze the different chemical species of 1 H, 13C, 15N, and 31P nuclei in solution and solid (not 1H) state. With the cross-polarization magic angle spinning (CP MAS) pulse sequence, the chemical structure of C and N can be characterized in situ nondestructively, and within a feasible time of analysis.[15,16] However, even with completion of detailed experiments on rates of signal generation and relaxation for each type of carbon,[17] quantitative analysis of NMR data is not possible in the presence of paramagnetic species. Samples containing charred materials cannot be quantified by the CP technique; instead, the C nuclei must be directly excited using a Bloch decay sequence.[18] Additional information on the structure of soil organic carbon (SOC) can be obtained by specific pulse sequences such as interrupted decoupling (ID), proton spin relaxation editing (PSRE), and mixing of proton spins (MOPS) (for 1203
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Table 1 Important degradative and nondegradative techniques to study SOM structure Technique Chemolytic techniques
Acid hydrolysis
Components addressed Address defined biomolecules released mostly as their monomer units from the organic matrix by an appropriate chemical treatment Polysaccharides
Proteinaceous compounds
Amino sugars
Solvent extraction
Extractable lipids
Saponification
Cutin and suberin components
CuO oxidation
Lignin
HNO3 oxidation
Analytical pyrolysis
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Pyrogenic carbon
Products of SOM released by thermal degradation
Analysis of defined organic components of plant, microbial and pyrogenic origin Often well-suited as biomarkers Distinguishes different types of polysaccharides by sequential extraction Pattern of monosaccharides released gives information on the source (plant vs. microorganisms) Comprises the dominant form of organic nitrogen in soil Assessment of D=L ratios Traces microbial input to SOM Distinguishes between fungal and bacterial residues Comprises hydrophobic aliphatic compounds of various origins Detects aliphatic biopolymers derived from vascular plants Traces plant input to SOM Informs about type of plant Informs about lignin decomposition in soil Detects aliphatic biopolymers derived from vascular plants Traces the highly aromatic core of charred organic components Pattern of pyrolysis products allows detailed information on the chemical composition of the parent molecules Well suited for biomarker analysis
Drawbacks Only about 60% (fresh organic residues) to about 20% (transformed, mineral-associated compounds) of SOM is characterized Not all polysaccharides are hydrolyzable
References [7,34]
[8,35]
Yield differs for different types of with organic matter
Only a part of the proteinaceous compounds is hydrolyzable Source of some amino sugars is not well defined
[36,37]
Complex and polymerized lipids are only scarcely accessible Does not comprise nonester plant biomacromolecules Only cleaves arylether bondings Yield is not defined and decreases with increasing lignin decomposition Does not comprise nonester plant biomacromolecules Yield varies with the type of the charred organic components
[39,40]
Volatilization of different types of pyrolysis fragments varies Pyrolysis fragments may have different sources Secondary pyrolysis reactions may occur
[22,38]
[25] [41,42]
[43] [44,45]
[11,12]
Organic Matter Structure and Characterization
Cutin and suberin components
Applications
Py-FIMS
Pyrolysis products that are volatile to be separated by gas chromatography Pyrolysis products are treated by soft ionization technique
Solution 13C, 1H, 15N, and 31P NMR spectroscopy
In particular aliphatic and benzenecarboxylic acids as their methyl esters Analysis of all C, H, N, or P species within a solid or soluble sample Analysis of C, H, N, and P species in aqueous samples
CP MAS 13C, and N spectroscopy
Analysis of C and N species in solid samples
Thermochemolysis with TMAH NMR spectroscopy
15
BD
13
C NMR spectroscopy
IR spectroscopy (FTIR and DRIFT)
Analysis of C species in solid samples Analysis of C species in solid samples
Separates pyrolysis products that have the same mass=charge (m=z) ratio Soft ionization produces predominantly molecular ions of the pyrolysis products Pyrolysis=methylation renders polar products volatile for gas chromatographic separation Signal intensity relates to the concentration of nuclei creating the signal Composition of C, H, and N species in the soil solution and in alkaline extracts (humic and fulvic acids) Characterization of the chemical structure of organic C and N in situ and nondestructively
Direct excitation of 13C spins enables analysis of charred materials Informs on the type of atoms to which C is bonded and on the nature of the bond
Nonvolatile pyrolysis products cannot be detected
[13]
Volatilization decreases with increasing polarity of the fragments Reproducibility needs to be improved
[11]
Most applications are not quantitative Insoluble compounds are not detected
Limited quantitative interpretation caused by paramagnetic species, by different C and N relaxation, by spinning side bands, and by the cross-polarization technique Very time consuming
Reveals only a few well-resolved peaks Signals from minerals often dominate
[46,47]
[15–17,48]
[49]
Organic Matter Structure and Characterization
Py-GC MS
[15,16]
[18]
[50] [19,50]
Key: SOM ¼ soil organic matter, Py-GC MS ¼ pyrolysis-gas chromatography mass spectrometry, Py-FIMS ¼ pyrolysis-field ionization mass spectrometry, TMAH ¼ tetramethylammonium hydroxide, NMR spectroscopy ¼ nuclear magnetic resonance spectroscopy, CP MAS NMR spectroscopy ¼ cross-polarization magic angle spinning nuclear magnetic resonance spectroscopy, BD NMR spectroscopy ¼ bloch decay nuclear magnetic resonance spectroscopy, IR spectroscopy ¼ infrared spectroscopy, FTIR ¼ fourier transform infrared spectroscopy, DRIFT ¼ diffuse reflectance infrared fourier transform spectroscopy.
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literature see Ref.[1].) Of the other spectroscopic techniques, infrared spectroscopy provides information on the type of atoms to which C is bonded and on the nature of the bond,[19] whereas electron spin resonance spectroscopy gives information about free radicals in SOM.[20]
CHEMICAL STRUCTURE OF SOIL ORGANIC MATTER Individual Plant and Microbial Components Individual components derived from plants (primary resources) and microorganisms (secondary resources) can be considered as the parent material of SOM. Within plant and microbial tissues, polysaccharides are generally the most important organic components. Analysis of sugar monomers released by hydrolysis or pyrolysis revealed that crystalline and noncrystalline
Organic Matter Structure and Characterization
plant polysaccharides are rapidly decomposed and microbial polysaccharides accumulate in soil.[8,21] Most amino sugars in soil are also of microbial origin, predominantly from fungal chitin and bacterial peptidoglycan.[22] An important biopolymer in soil is vascular plant-derived lignin with its p-hydroxyphenyl, guaiacyl, and syringyl monomeric units. The pattern of lignin monomers can be used to identify the primary resource of SOM; in contrast to angiosperm lignin, gymnosperm lignin does not contain syringyl units. In soil, lignin is decomposed in aerobic environments via side-chain oxidation and ring opening.[23,24] This results in a shortening of alkyl side-chains and an increase in carbonyl and carboxyl groups. Thus, parts of the lignin degradation products are water soluble[23] and represent, together with the polysaccharides, the majority of the dissolved organic matter in soil.[6] The third major component is free and bound lipids of plant and microbial origin, including waxes, organic acids, steroids, glycerides, and phospholipids.[3,25]
Fig. 1 (A) Thermograms for compound classes evolved by pyrolysis-field ionization from clay (above), fine silt (center), and medium silt (below) from a humus formation experiment after 13 and 34 years of soil development (From Ref.[11]) and (B) solid-state 13C NMR spectra of the clay fraction isolated from soils of different pedogenesis. (From Ref.[10].)
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Organic Matter Structure and Characterization
Plant cutin and suberin (insoluble polyesters) can be easily decomposed,[26] while nonsaponifiable cutan and suberan (insoluble nonpolyesters) appear to be resistant to degradation.[27] Some aliphatic compounds of microbial origin are also selectively preserved.[28]
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and concepts on SOM structure, the excellent reviews of Ko¨gel-Knabner,[10] Baldock and Nelson,[1] and Hedges et al.[32] are recommended.
REFERENCES The Soil Organic Matter Continuum Soil organic matter is generally composed of the above-mentioned plant and microbial residues, and their transformation products.[7,29] The latter refers largely to the term ‘‘humic substances’’ as frequently used in older references e.g.,[30,31] Recently, there has been a shift in paradigm away from humic substances. Organic matter degradation is considered to be predominantly a process of attrition, during which relatively resistant biomolecules are selectively concentrated.[32] In surface soil horizons with large inputs of plant residues, the SOM continuum varying from fresh residues to highly degraded components is dominated by the former material.[7] In contrast, SOM in subsoil horizons is enriched by highly-altered, recalcitrant organic materials that can only be characterized to a minor extent by chemolytic treatments.[32] Accessibility of these compounds is limited to (chemo)thermolytic and spectroscopic methods. In aging SOM, Schulten, Leinweber, and Reuter[33] and Schulten and Leinweber[11] observed that increasing amounts of thermal energy applied in pyrolysis-field ionization mass spectrometry were required for volatilizing lignin dimers, alkylaromatics, and lipids (Fig. 1A). The authors suggested that the development of stronger chemical bonds was due to either formation of threedimensional crosslinking by aryl–alkyl combinations or by formation of strong organic–mineral complexes. Ko¨gel-Knabner[7] concluded from ID pulse sequences at 13C NMR spectroscopy that cross-linked aliphatic compounds accumulate during SOM decomposition. The pedogenic environment has a large impact on the structure of SOM. This can be particularly confined by solid-state 13C NMR spectroscopy of mineralassociated organic matter, while spectra obtained on bulk samples are influenced by plant residues that are rather similar in composition.[10] The Mollisol in Fig. 1B is characterized by about similar contributions of alkyl (0–50 ppm), O-alkyl (50–110 ppm), aromatic (110–160 ppm) and carboxyl/amide (160–200 ppm) carbon. In contrast, Alfisols and Ultisols show a high proportion of alkyl and O-alkyl C, and Spodosols are dominated by alkyl C. Future work may benefit from the application of microscopic and nondestructive microspectroscopic techniques to investigate SOM within its mineral and microbiological soil environment. For in-depth information on modern methodological approaches
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1. Baldock, J.A.; Nelson, P.N. Soil organic matter. In Handbook of Soil Science; Sumner, M.E., Ed.; CRC Press: Boca Raton, FL, 2000; B-25–B-84. 2. Swift, R.S. Organic matter characterisation. In Methods of Soil Analysis. Part 3. Chemical Methods; Sparks, D.L., Ed.; Soil Science Society of America: Madison, WI, 1996; 1011–1069. 3. Stevenson, F.J.; Elliott, E.T. Methodologies for assessing the quantity and quality of soil organic matter. In Dynamics of Soil Organic Matter in Tropical Ecosystems; Coleman, D.C., Oades, J.M., Uehara, G., Eds.; University of Hawaii Press: Honolulu, HI, 1989; 173–199. 4. Christensen, B.T. Carbon in primary and secondary organomineral complexes. In Structure and Organic Matter Storage in Agricultural Soils; Carter, M.R., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1996; 97–165. 5. Golchin, A.; Oades, J.M.; Skjemstad, J.O.; Clarke, P. Soil structure and carbon cycling. Aus. J. Soil Res. 1994, 32, 1043–1068. 6. Guggenberger, G.; Zech, W.; Schulten, H.-R. Formation and mobilization pathways of dissolved organic carbon: evidence from chemical structural studies of organic carbon fractions in acid forest floor solutions. Org. Geochem. 1994, 21, 51–66. 7. Ko¨gel-Knabner, I. Biodegradation and humification processes in forest soils. In Soil Biochemistry; Bollag, J.-M., Stotzky, G., Eds.; Marcel Dekker: New York, NY, 1993; Vol. 8, 101–137. 8. Guggenberger, G.; Christensen, B.T.; Zech, W. Land-use effects on the composition of organic matter in particle-size separates of soils: I. lignin and carbohydrate signature. Eur. J. Soil Sci. 1994, 45, 449–458. 9. Hedges, J.I.; Oades, J.M. Comparative organic geochemistries of soils and sediments. Org. Geochem. 1997, 27, 319–361. 10. Ko¨gel-Knabner, I. Analytical approaches for characterizing soil organic matter. Org. Geochem. 2000, 31, 609–625. 11. Schulten, H.-R.; Leinweber, P. Characterization of humic and soil particles by analytical pyrolysis and computer modeling. J. Anal. Appl. Pyrol. 1996, 38, 1–53. 12. Saiz-Jimenez, C. Analytical pyrolysis of humic substances: pitfalls, limitations and possible solutions. Environ. Sci. Technol. 1994, 28, 1773–1780. 13. Van Bergen, P.; Flannery, M.B.; Poulton, P.R.; Evershed, R.P. Organic geochemical studies of soils from Rothamsted experimental station: III. Nitrogencontaining organic matter in soil from geescroft wilderness. In Fate of N-Containing Macromolecules in the Biosphere and Geosphere; Stankiewicz, B.A., van Bergen, P.F., Eds.; Symposium Series 707; American
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Chemical Society, Oxford University Press: England, 1998; 321–338. Saiz-Jimenez, C. The chemical structure of humic substances: recent advances. In Humic Substances in Terrestrial Ecosystems; Piccolo, A., Ed.; Elsevier: Amsterdam, The Netherlands, 1996; 1–44. Knicker, H.; Nanny, M.A. Nuclear magnetic resonance spectroscopy. basic theory and background. In NMR Spectroscopy in Environmental Science and Technology; Nanny, M.A., Minear, R.A., Leenheer, J.A., Eds.; Oxford University Press: London, England, 1997; 3–15. Skjemstad, J.O.; Clarke, P.; Golchin, A.; Oades, J.M. Characterisation of soil organic matter by solid-state 13 C nmr spectroscopy. In Driven by Nature: Plant Litter Quality and Decomposition; Giller, K.E., Ed.; CAB International: Wallingford, England, 1997; 253–271. Pfeffer, P.E.; Gerasimowicz, W.V. Nuclear Magnetic Resonance in Agriculture; CRC Press: Boca Raton, FL, 1989. Skjemstad, J.O.; Clarke, P.; Taylor, J.A.; Oades, J.M.; McClure, S.G. The chemistry and nature of protected carbon in soil. Aust. J. Soil Res. 1996, 34, 251–271. Piccolo, A.; Conte, P. Advances in nuclear magnetic resonance and infrared spectroscopies of soil organic particles. In Structure and Surface Reactions of Soil Particles; Huang, P.M., Senesi, N., Buffle, J., Eds.; John Wiley & Sons: Chichester, England, 1998; 183–250. Cheshire, M.V.; Senesi, N. Electron spin resonance spectroscopy of organic and mineral soil particles. In Structure and Surface Reactions of Soil Particles; Huang, P.M., Senesi, N., Buffle, J., Eds.; Wiley: Chichester, England, 1998; 325–376. Huang, Y.; Eglinton, G.; VanderHage, E.R.E.; Boon, J.J.; Bol, R.; Ineson, P. Dissolved organic matter in grass upland soil horizons studied by analytical pyrolysis techniques. Eur. J. Soil Sci. 1998, 49, 1–15. Parsons, J.W. Chemistry and distribution of amino sugars in soils and soil organisms. In Soil Biochemistry; Paul, E.A., Ladd, J.N., Eds.; Marcel Dekker: New York, NY, 1981; Vol. 5, 197–227. Haider, K. Problems related to the humification processes in soils of the temperate climate. In Soil Biochemistry; Bollag, J.-M., Stotzky, G., Eds.; Marcel Dekker: New York, NY, 1992; Vol. 7, 55–94. Shevchenko, S.M.; Bailey, G.W. Life after death: lignin– humic relationships reexamined. Critical Rev. Environ. Sci. Technol. 1996, 26, 95–153. Ko¨gel-Knabner, I.; Ziegler, F.; Riederer, M.; Zech, W. Distribution and decomposition pattern of cutin and suberin in forest soils. Z. Pflanzenerna¨hr. Bodenk. 1989, 152, 409–413. Riederer, M.; Matzke, K.; Ziegler, F.; Ko¨gel-Knanber, I. Inventories and decomposition of the lipid plant biopolymers cutin and suberin in temperate forest soils. Org. Geochem. 1993, 20, 1063–1076. Tegelaar, E.W.; de Leeuw, J.W.; Saiz-Jimenez, C. Possible origin of aliphatic moieties in humic substances. Sci. Total Environ. 1989, 81=82, 1–17. Lichfouse, E.; Chenu, C.; Baudin, F.; Leblond, C.; da Silva, M.; Behar, F.; Derenne, S.; Largeau, C.;
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Wehrung, P.; Albrecht, P. A novel pathway of soil organic matter formation by selective preservation of resistant straight-chain biopolymers: chemical and isotopic evidence. Org. Geochem. 1998, 28, 411–415. Waksman, S.A. Humus, Origin, Chemical Composition and Importance in Nature; Ballie´re, Tindall & Cox: London, England, 1938. Aiken, G.R.; McKnight, D.M.; Wershaw, R.L.; MacCarthy, P. Humic Substances in Soil, Sediment and Water; John Wiley & Sons: New York, NY, 1985. Hayes, M.H.B.; MacCarthy, P.; Malcolm, R.; Swift, R.S. Humic Substances II. In Search of Structure; Wiley Interscience: Chichester, England, 1989. Hedges, J.I.; Eglinton, G.; Hatcher, P.G.; Kirchman, D.L.; Arnosti, C.; Derenne, S.; Evershed, R.P.; Ko¨gel-Knabner, I.; de Leeuw, J.W.; Littke, R.; Michaelis, W.; Rullko¨tter, J. The molecularlyuncharacterized component of nonliving organic matter in natural environments. Org. Geochem. 2000, 31, 945–958. Schulten, H.-R.; Leinweber, P.; Reuter, G. Initial formation of soil organic matter from grass residues in a long-term experiment. Biol. Fertil. Soils 1992, 14, 237–245. Stevenson, F.J. Humus Chemistry, Genesis, Composition, Reactions, 2nd Ed.; John Wiley & Sons: New York, NY, 1994. Cheshire, M.V. Nature and Origin of Carbohydrates; Academic Press: London, England, 1979. Chen, C.-N.; Shufeldt, R.C.; Stevenson, F.J. Amino acid analysis of soils and sediments: extraction and desalting. Soil Biol. Biochem. 1975, 7, 143–151. Amelung, W.; Zhang, X. Determination of amino acid enantiomers in soils. Soil Biol. Biochem. 2001, 33, 553–562. Amelung, W. Methods using amino sugars as markers for microbial residues in soil. In Assessment Methods for Soil Carbon; Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., Eds.; Lewis Publishers: Boca Raton, FL, 2001; 233–272. Dinel, H.; Schnitzer, M.; Mehuys, G.R. Soil lipids origin, nature, content, decomposition and effect on soil physical properties. In Soil Biochemistry; Bollag, J.-M., Stotzky, G., Eds.; Marcel Dekker: New York, NY, 1990; Vol. 5, 397–429. Capriel, P.; Beck, T.; Borchert, H.; Ha¨rter, P. Relationship between soil aliphatic fraction extracted with supercritical hexane, soil microbial biomass, and soil aggregate stability. Soil Sci. Soc. Am. J. 1990, 54, 415–420. Ertel, J.R.; Hedges, J.I. The lignin component of humic substances: distribution among soil and sedimentary humic, fulvic, and base-insoluble fractions. Geochim. Cosmochim. Acta 1984, 48, 2065–2074. Ko¨gel-Knabner, I.; Zech, W.; Hatcher, P.G. Chemical structural studies of forest soil humic acids: aromatic carbon fraction. Soil Sci. Soc. Am. J. 1991, 55, 241–247. Gon˜i, M.A.; Hedges, J.I. Potential applications of cutin-derived cuo reaction products for discriminating vascular plant sources in natural environments. Geochim. Cosmochim. Acta 1990, 54, 23,073–23,081.
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44. Glaser, B.; Haumaier, L.; Guggenberger, G.; Zech, W. Black carbon in soils: the use of benzencarboxylic acids as specific markers. Org. Geochem. 1998, 29, 811–819. 45. Glaser, B.; Haumaier, L.; Guggenberger, G.; Zech, W. The terra preta phenomenon: a model for sustainable agriculture in the humid tropics. Naturwissenschaften 2001, 88, 37–41. 46. del Rio, J.C.; McKinney, D.E.; Knicker, H.; Nanny, M.A.; Minard, R.D.; Hatcher, P.G. Structural characterization of bio- and geo-macromolecules by off-line thermochemolysis with tetramethylammonium hydroxide. J. Chromatogr. 1998, 823, 433–448. 47. Filley, T.R.; Minard, R.D.; Hatcher, P.G. Tetramethylammonium hydroxide (TMAH) thermochemolysis:
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proposed mechanisms based upon the application of 13 C-labeled TMAH to a synthetic model lignin dimer. Org. Geochem. 1999, 30, 607–621. 48. Preston, C.M. Applications of NMR to soil organic matter analysis: history and prospects. Soil Sci. 1996, 161, 144–166. 49. Preston, C.M. Review of solution NMR of humic substances. In NMR of Humic Substances and Coal; Wershaw, R.L., Mikita, M.A., Eds.; Lewis Publishers: Chelsea, MI, 1987; 3–32. 50. Parfitt, R.L.; Fraser, A.R.; Farmer, V.C. Adsorption on hydrous oxides III. Fulvic acid and humic acid on goethite, gibbsite and imogolite. J. Soil Sci. 1977, 28, 289–296.
Organic Matter Turnover Johan Six Colorado State University, Fort Collins, Colorado, U.S.A.
Julie D. Jastrow Argonne National Laboratory, Argonne, Illinois, U.S.A.
INTRODUCTION Soil organic matter (SOM) is a dynamic entity. The amount (stock) of organic matter in a given soil can increase or decrease depending on numerous factors including climate, vegetation type, nutrient availability, disturbance, land use, and management practices. But even when stocks are at equilibrium, SOM is in a continual state of flux; new inputs cycle—via the process of decomposition—into and through organic matter pools of various qualities and replace materials that are either transferred to other pools or mineralized. For the functioning of a soil ecosystem, this ‘‘turnover’’ of SOM is probably more significant than the sizes of SOM stocks.[1] An understanding of SOM turnover is crucial for quantifying C and nutrient cycles and for determining the quantitative and temporal responses of local, regional, or global C and nutrient budgets to perturbations caused by human activities or climate change.[2]
DEFINITION OF SOIL ORGANIC MATTER TURNOVER The turnover of an element (e.g., C, N, P) in a pool is generally determined by the balance between inputs (I) and outputs (O) of the element to and from the pool Fig. 1. Turnover is most often quantified as the element’s mean residence time (MRT) or its half-life (T1=2). The MRT of an element in a pool is defined as 1) the average time the element resides in the pool at steady state or 2) the average time required to completely renew the content of the pool at steady state. The term half-life is adopted from radioisotope work, where it is defined as the time required for half of a population of elements to disintegrate. Thus, the half-life of SOM is the time required for half of the currently existing stock to decompose. The most common model used to describe the dynamic behavior or turnover of SOM is the firstorder model, which assumes constant zero-order 1210 Copyright © 2006 by Taylor & Francis
input with constant proportional mass loss per unit time[3,4]
@S ¼ I kS; @t
ð1Þ
where S is the SOM stock, t is the time, k is the decomposition rate, and kS is equivalent to output O. Assuming equilibrium (I ¼ O), the MRT can then be calculated as MRT ¼
1 k
ð2Þ
and MRT and T1=2 can be calculated interchangeably with the formula MRT ¼ T1=2 = ln 2
ð3Þ
MEASURING SOIL ORGANIC MATTER TURNOVER Most often the turnover of SOM, more specifically the turnover of SOM-C, is estimated by one of four techniques: 1. Simple first-order modeling 2. 13C natural abundance technique 3. 14C dating technique 4. ‘‘bomb’’ 14C technique. This list does not include tracer studies where a substrate (e.g., plant material) enriched in 13C, 14C, and=or 15 N is added to soil, and its fate is followed over time. Most studies of this type (see Ref.[5] for a review) use the tracers to quantify the short-term (1–5 yr) decomposition rate of freshly added material rather than the long-term turnover of whole-soil C. Eqs. (1) and (2) form the basis for estimates of SOM turnover derived from first-order modeling; the unknown k is calculated as
k ¼
I S
Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001812 Copyright # 2006 by Taylor & Francis. All rights reserved.
Organic Matter Turnover
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Fig. 1 The turnover of soil organic matter (SOM) is determined by the balance of inputs and outputs. Total SOM consists of many different pools that are turning over at different rates. The mean residence time (MRT) of total SOM is a function of the turnover rates of its constituent pools.
the change (t ¼ 0). An average value of I can then be calculated
by assuming a steady state
@S ¼ 0: @t
I ¼ kSe ;
This approach requires estimates of annual C input rates, which can be assumed to be continuous or discrete.[3] The input can also be written as I ¼ hA where A is the annual addition of C as fresh residue and h (the isohumification coefficient) represents the fraction that, after a rapid initial decomposition of A, remains as the actual annual input to S. An estimate of h is then necessary. A value of 0.3 is commonly used for agricultural crops, but the value can be higher for other materials such as grasses or peat.[6,7] Another approach to estimate k by first-order modeling is ‘‘chronosequence modeling.’’[8] An increase (or decrease) in C across a chronosequence of change in vegetation, land use, or management practice can be fitted to a first-order model Se S0 kt e S ¼ Se 1 Se
MRT ¼
which is equivalent to S ¼ S0 þ ðSe S0 Þð1 e kt Þ
ð4Þ
where t is the time since the change, Se is the C content at equilibrium, and S0 is the initial C content before
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but in this case I represents annual inputs of new SOM (hA) rather than inputs of fresh litter or detritus. This approach is also used for chronosequences of primary succession (e.g., on glacial moraines, volcanic deposits, river terraces, dune systems), in this case S0 ¼ 0.[4] The 13C natural abundance technique relies on 1) the difference in 13C natural abundance between plants with different photosynthetic pathways [Calvin cycle (C3 plants) vs. Hatch–Slack cycle (C4 plants)]; and 2) the assumption that the 13C natural abundance signature of SOM is identical to the 13C natural abundance signature of the plants from which it is derived.[9] Thus, where a change in vegetation type has occurred at some known point in time, the rate of loss of the C derived from the original vegetation and the incorporation of C derived from the new vegetation can be inferred from the resulting change in the 13C natural abundance signature of the soil. The turnover of C derived from the original vegetation is then calculated by using the first-order decay model 1 t ¼ k lnðSt =S0 Þ
ð5Þ
where t is the time since conversion, St is the C content derived from original vegetation at time t, and S0 is the C content at t ¼ 0. For further details on the technique see Refs.[9,10].
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Organic Matter Turnover
The presence of 14C with a half-life of 5570 yr in plants and the transformation of this 14C into SOM with little isotopic discrimination allows the SOM to be dated, providing an estimate of the age of the SOM. The 14C dating technique is applicable within a time frame of 200–40,000 yr; samples with an age less than 200 yr are designated as modern (See Ref.[11] for further details of the methodology.) Thermonuclear bomb tests in the 1950s and 1960s caused the atmospheric 14C content to increase sharply and then to fall drastically after the tests were halted. This sequence of events created an in situ tracer experiment; the incorporation of bomb-produced radiocarbon into SOM after the tests stopped allows estimates of the turnover of SOM. Further details of the technique are described in Refs.[2,12,13] RANGE AND VARIATION IN ESTIMATES OF TOTAL SOIL ORGANIC MATTER TURNOVER Comparisons of MRT values estimated by the four methods previously described (see, also, Table 1) reveal a wide range of MRTs. Although variations within each method are attributable to differences in vegetation, climate, soil type, and other factors, the largest variations in observed MRTs are method dependent. For example, MRTs estimated by simple first-order modeling and 13C natural abundance are generally
smaller by an order of magnitude than MRTs estimated by radiocarbon dating, because of the different time scales that the two methods measure. The 13C method is generally used in medium-term observations or experiments (5–50 yr); hence, this method gives an estimate of turnover dominated by relatively recent inputs and C pools that cycle within the time frame of the experiment. In contrast, the oldest and most recalcitrant C pools dominate estimates by radiocarbon dating because of the long-term time frame (200–40,000 yr) that this method measures.[11]
FACTORS CONTROLLING SOIL ORGANIC MATTER TURNOVER Primary production (specifically, the rate of organic matter transfer below-ground) and soil microbial activity (specifically, the rates of SOM transformation and decay) are recognized as the overall biological processes governing inputs and outputs and, hence, SOM turnover. These two processes (and the balance between them) are controlled by complex underlying biotic and abiotic interactions and feedbacks, most of which can be tied in some way to the state factor model of soil formation.[4] Climate (especially temperature and precipitation) constrains both production and decomposition of SOM. Vegetation type affects
Table 1 Range and average mean residence times (MRTs) of total soil organic C in various ecosystem types as estimated by four different methods MRT (yr) Method and ecosystem First-order modeling Cultivated systems and recovering grassland or woodland systems
Sites and sourcesa 7=7
Highb
Average SEc
[14]
102[15]
67 12
Lowb 15
13
C natural abundance Cultivated systems Pasture systems Forest systems
20=10 12=10 2=2
18[16] 17[18] 18[20]
165[17] 102[19] 25[21]
61 9 38 7 22 4
Radiocarbon agingd Cultivated systems Grassland systems Forest systems
21=8e 4=3f 4=3
327[22] Modern[23] 422[22]
1770[23] 1040[24] 1550[25]
880 105 —g 1005 184
‘‘Bomb’’ 14C analysis Cultivated systems Forest and grassland systems
1=1 14=12
1863[13] 36[26]
1863[13] 1542[27]
1863g 535 134
a
First value indicates the number of sites used to calculate average MRT values; second value indicates the number of literature sources surveyed (i.e., some sources provided data for multiple sites). b Number in parentheses indicates reference to literature. c SE, standard error. d Values presented in MRT columns for this technique are radiocarbon ages in years B.P. e Includes two sites dating as ‘‘modern.’’ f Includes three sites dating as ‘‘modern.’’ g Only one value available.
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Organic Matter Turnover
1213
production rates and the types and quality of organic inputs (e.g., below- vs. above-ground, amounts of structural tissue, C=N and lignin=N ratios), as well as the rates of water and nutrient uptake—all of which, in turn, influence decomposition rates. The types, populations, and activities of soil biota control decomposition and nutrient cycling=availability and hence influence vegetative productivity. Parent material affects SOM turnover as soil type, mineralogy, texture, and structure influence pH, water and nutrient supply, aeration, and the habitat for soil biota, among other factors. Topography modifies climate, vegetation type, and soil type on the landscape scale and exerts finerscale effects on temperature, soil moisture, and texture. Lastly, time affects whether inputs and outputs are at equilibrium, and temporal scale influences the relative importance of various state factor effects on production and decomposition. Disturbance or management practices also exert considerable influence on SOM turnover via direct effects on inputs and outputs and through indirect effects on the factors controlling these fluxes. An example of management effects on MRT is illustrated in Table 2; in most cases, the MRT of whole-soil C is significantly longer under no tillage agriculture than under conventional tillage practices.
TURNOVER OF DIFFERENT SOIL ORGANIC MATTER POOLS The previous discussion is focused on the turnover and MRT of whole-soil C; hence, it treats SOM as a single, homogeneous reservoir. But, in fact, SOM is a
heterogeneous mixture consisting of plant, animal, and microbial materials in all stages of decay combined with a variety of decomposition products of different ages and levels of complexity. Thus, the turnover of these components varies continuously, and any estimate of MRT for SOM as a whole merely represents an overall average value (Fig. 1). Although average MRTs are useful for general comparisons of sites or the effects of different management practices, they can be misleading because soils with similar average MRTs can have very different distributions of organic matter among pools with fast, slow, and intermediate turnover rates.[2,31] Simulation models that account for variations in turnover rates for different SOM pools are now used to generate more realistic descriptions of SOM dynamics. A few models represent decomposition as a continuum, with each input cohort following a pattern of increasing resistance to decay,[32] but most models are multicompartmental, with several organic matter pools (often 3–5) that are kinetically defined with differing turnover rates. For example, the CENTURY SOM model[33] divides soil C into active, slow, and passive pools, with MRTs of 1.5, 25, and about 1000 yr, respectively, and separates plant inputs into metabolic (readily decomposable; MRT of 0.1–1 yr) and structural (difficult to decompose; MRT of 1–5 yr) pools as a function of lignin : N ratio. Even though compartmental models are reasonably good at simulating changes in SOM, the compartments are conceptual in nature, and thus it has been difficult to relate them to functionally meaningful pools or experimentally verifiable fractions.[34,35] The use of isotopic techniques to analytically determine the MRTs of physically and chemically
Table 2 Effect of tillage practices on mean residence time (MRT) of total soil organic C estimated by the 13C natural abundance technique Cropping systema
Site (Ref.) [28]
Wheat–fallow (NT)
Sidney, NE
Depth (cm)
tb (yr)
MRT (yr)
0–20
26
73
0–20
5
26
0–30
17
127
0–30
11
118
Wheat–fallow (CT) Delhi, Ont.[29]
Corn (NT)
44
Corn (CT) Boigneville, France[16]
Corn (NT)
14
Corn (CT) Rosemount, MN[30]
Corn (NT, 200 kg N ha1 yr1)
55
Corn (CT, 200 kg N ha1 yr1)
73
Corn (NT, 0 kg N ha1 yr1)
54
Corn (CT, 0 kg N ha1 yr1) Average SE
c
a
NT, no tillage; CT, conventional (moldboard plow) tillage. b Time period of experiment. c SE, standard error.
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72 NT
80 19
CT
52 11
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Organic Matter Turnover
Table 3 Mean residence time (MRT) of macro- and microaggregate-associated C estimated by the 13C natural abundance technique
macroaggregates vs. microaggregates show consistently slower turnovers in microaggregates (Table 3). Thus, a much higher proportion of the SOM occluded in microaggregates consists of stabilized materials with relatively long MRTs.
Aggregate size classa
lm
MRT (yr)
Tropical pasture[44]
M m
>200 250 50–250
14 61
Corn[47]
M m
>250 50–250
42 691
Wheat–fallow, no tillage[48]
M m
250–2000 53–250
27 137
Wheat–fallow, conventional tillage[48]
M m
250–2000 53–250
8 79
Average SEb
M m
1. Paul, E.A. Dynamics of organic matter in soils. Plant Soil 1984, 76, 275–285. 2. Trumbore, S.E. Comparison of carbon dynamics in tropical and temperate soils using radiocarbon measurements. Global Biogeochem. Cycles 1993, 7, 275–290. 3. Olson, J.S. Energy storage and the balance of producers and decomposers in ecological systems. Ecology 1963, 44, 322–331. 4. Jenny, H. The Soil Resource—Origin and Behavior; Springer: New York, 1980; 377 pp. 5. Schimel, D.S. Theory and Application of Tracers; Academic Press: San Diego, CA, 1993; 119 pp. 6. Buyanovsky, G.A.; Kucera, C.L.; Wagner, G.H. Comparative analyses of carbon dynamics in native and cultivated ecosystems. Ecology 1987, 68, 2023–2031. 7. Jenkinson, D.S. The turnover of organic carbon and nitrogen in soil. Phil. Trans. R. Soc. Lond. Ser. B 1990, 329, 361–368. 8. Jastrow, J.D. Soil aggregate formation and the accrual of particulate and mineral-associated organic matter. Soil Biol. Biochem. 1996, 28, 665–676. 9. Cerri, C.; Feller, C.; Balesdent, J.; Victoria, R.; Plenecassagne, A. Application du tracage isotopique natural en 13 C a l’etude de la dynamique de la matiere oganique dans les sols. C.R. Acad. Sci. Paris Ser. II 1985, 300, 423–428. 10. Balesdent, J.; Mariotti, A. Measurement of soil organic matter turnover using 13C natural abundance. In Mass Spectrometry of Soils; Boutton, T.W., Yamasaki, S., Eds.; Marcel Dekker: New York, 1996; 83–111. 11. Goh, K.M. Carbon dating. In Carbon Isotope Techniques; Coleman, D.C., Fry, B., Eds.; Academic Press: San Diego, CA, 1991; 125–145. 12. Goh, K.M. Bomb carbon. In Carbon Isotope Techniques; Coleman, D.C., Fry, B., Eds.; Academic Press: San Diego, CA, 1991; 147–151. 13. Harrison, K.G.; Broecker, W.S.; Bonani, G. The effect of changing land use on soil radiocarbon. Science 1993, 262, 725–726. 14. Hendrix, P.F. Long-term patterns of plant production and soil carbon dynamics in a georgia piedmont agroecosystem. In Soil Organic Matter in Temperate Agroecosystems: Long-Term Experiments in North America; Paul, E.A., Paustian, K., Elliott, E.T., Cole, C.V., Eds.; CRC Press: Boca Raton, FL, 1997; 235–245. 15. Buyanovsky, G.A.; Brown, J.R.; Wagner, G.H. Sanborn field: effect of 100 years of cropping on soil parameters influencing productivity. In Soil Organic Matter in Temperate Agroecosystems: Long-Term Experiments in North America; Paul, E.A., Paustian, K., Elliott, E.T., Cole, C.V., Eds.; CRC Press: Boca Raton, FL, 1997; 205–225.
Ecosystem (Ref.)
a
42 18 209 95
M, macroaggregate; m, microaggregate. SE, standard error.
b
separated SOM fractions has demonstrated the existence of various turnover rates for different pools. For example, low-density SOM (except for charcoal) invariably turns over faster than high-density, mineral-associated SOM, and hydrolyzable SOM turns over faster than nonhydrolyzable residues.[36,37] The MRTs of primary organomineral associations generally increase with decreasing particle size, although there are exceptions (particularly among fine gradations of silt- and clay-sized particles) that have been variously related to climate, clay mineralogy, and fractionation methodology.[34,38,39] For a given set of biotic and abiotic conditions, the turnover of different SOM pools depends mechanistically on the quality and biochemical recalcitrance of the organic matter and its accessibility to decomposers. With other factors equal, clay soils retain more SOM with longer MRTs than do sandy soils.[40] Readily decomposable materials can become chemically protected from decomposition by association with clay minerals and by sorption to humic colloids.[38,41] Clay mineralogy also plays an important role. For example, montmorillonitic clays and allophanes generally afford more protection than illites and kaolinites.[42] In addition, the spatial location of SOM within the soil matrix determines its physical accessibility to decomposers. Relatively labile material may become physically protected by incorporation into soil aggregates[43] or by deposition in micropores inaccessible even to bacteria. Studies of the average MRTs of organic matter in
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Organic Matter Turnover
16. Balesdent, J.; Mariotti, A.; Boisgontier, D. Effect of tillage on soil organic carbon mineralization estimated from 13C abundance in maize fields. J. Soil Sci. 1990, 41, 587–596. 17. Vitorello, V.A.; Cerri, C.C.; Andreux, F.; Feller, C.; Victoria, R.L. Organic matter and natural carbon-13 distributions in forested and cultivated oxisols. Soil Sci. Soc. Am. J. 1989, 53, 773–778. 18. Desjardins, T.; Andreux, F.; Volkoff, B.; Cerri, C.C. Organic carbon and 13C contents in soils and soil sizefractions, and their changes due to deforestation and pasture installation in Eastern Amazonia. Geoderma 1994, 61, 103–118. 19. Jastrow, J.D.; Boutton, T.W.; Miller, R.M. Carbon dynamics of aggregate-associated organic matter estimated by carbon-13 natural abundance. Soil Sci. Soc. Am. J. 1996, 60, 801–807. 20. Martin, A.; Mariotti, A.; Balesdent, J.; Lavelle, P.; Vuattoux, R. Estimate of organic matter turnover rate in a savanna soil by 13C natural abundance measurements. Soil Biol. Biochem. 1990, 22, 517–523. 21. Trouve, C.; Mariotti, A.; Schwartz, D.; Guillet, B. Soil organic carbon dynamics under eucalyptus and pinus planted on savannas in the congo. Soil Biol. Biochem. 1994, 26, 287–295. 22. Paul, E.A.; Collins, H.P.; Leavitt, S.W. Dynamics of resistant soil carbon of midwestern agricultural soils measured by naturally-occurring 14C abundance. Geoderma 2001, 104, 239–256. 23. Paul, E.A.; Follett, R.F.; Leavitt, S.W.; Halvorson, A.; Peterson, G.A.; Lyon, D.J. Radiocarbon dating for determination of soil organic matter pool sizes and dynamics. Soil Sci. Soc. Am. J. 1997, 61, 1058–1067. 24. Jenkinson, D.S.; Harkness, D.D.; Vance, E.D.; Adams, D.E.; Harrison, A.F. Calculating net primary production and annual input of organic matter to soil from the amount and radiocarbon content of soil organic matter. Soil Biol. Biochem. 1992, 24, 295–308. 25. Trumbore, S.E.; Bonani, G.; Wolfli, W. The rates of carbon cycling in several soils from AMS 14C measurement of fractionated soil organic matter. In Soils and the Greenhouse Effect; Bouwman, A.F., Ed.; Wiley: London, 1990; 407–414. 26. O’Brien, B.J. Soil organic carbon fluxes and turnover rates estimated from radiocarbon enrichments. Soil Biol. Biochem. 1984, 16, 115–120. 27. Bol, R.A.; Harkness, D.D.; Huang, Y.; Howard, D.M. The influence of soil processes on carbon isotope distribution and turnover in the british uplands. Eur. J. Soil Sci. 1999, 50, 41–51. 28. Six, J.; Elliott, E.T.; Paustian, K.; Doran, J.W. Aggregation and soil organic matter accumulation in cultivated and native grassland soils. Soil Sci. Soc. Am. J. 1998, 62, 1367–1377. 29. Ryan, M.C.; Aravena, R.; Gillham, R.W. The use of 13C natural abundance to investigate the turnover of the microbial biomass and active fractions of soil organic matter under two tillage treatments. In Soils and Global Change; Lal, R., Kimble, J., Levine, E., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1995; 351–360. 30. Clapp, C.E.; Allmaras, R.R.; Layese, M.F.; Linden, D.R.; Dowdy, R.H. Soil organic carbon and 13C
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31.
32.
33.
34.
35.
36.
37.
38.
39. 40.
41.
42.
43. 44.
45.
46.
47.
48.
abundance as related to tillage, crop residue, and nitrogen fertilization under continuous corn management in Minnesota. Soil Till. Res. 2000, 55, 127–142. Davidson, E.A.; Trumbore, S.E.; Amundson, R. Soil warming and organic carbon content. Nature 2000, 408, 789–790. ˚ gren, G.I.; Bosatta, E. Theoretical analysis of the longA term dynamics of carbon and nitrogen in soils. Ecology 1987, 68, 1181–1189. Parton, W.J.; Schimel, D.S.; Cole, C.V.; Ojima, D.S. Analysis of factors controlling soil organic matter levels in great plains grasslands. Soil Sci. Soc. Am. J. 1987, 51, 1173–1179. Balesdent, J. The significance of organic separates to carbon dynamics and its modeling in some cultivated soils. Eur. J. Soil Sci. 1996, 47, 485–493. Christensen, B.T. Matching measurable soil organic matter fractions with conceptual pools in simulation models of carbon turnover: revision of model structure. In Evaluation of Soil Organic Matter Models; Powlson, D.S., Smith, P., Smith, J.U., Eds.; Springer: Berlin, 1996; 143–159. Martel, Y.A.; Paul, E.A. The use of radiocarbon dating of organic matter in the study of soil genesis. Soil Sci. Soc. Am. Proc. 1974, 38, 501–506. Trumbore, S.E.; Chadwick, O.A.; Amundson, R. Rapid exchange between soil carbon and atmospheric carbon dioxide driven by temperature change. Science 1996, 272, 393–396. Christensen, B.T. Physical fractionation of soil and organic matter in primary particle size and density separates. Adv. Soil Sci. 1992, 20, 1–90. Feller, C.; Beare, M.H. Physical control of soil organic matter dynamics in the tropics. Geoderma 1997, 79, 69–116. Sorensen, L.H. The influence of clay on the rate of decay of amino acid metabolites synthesized in soils during decomposition of cellulose. Soil. Biol. Biochem. 1974, 7, 171–177. Jenkinson, D.S. Soil organic matter and its dynamics. In Russell’s Soil Conditions and Plant Growth; Wild, A., Ed.; Wiley: New York, 1988; 564–607. Dalal, R.C.; Bridge, B.J. Aggregation and organic matter storage in sub-humid and semi-arid soils. In Structure and Organic Matter Storage in Agricultural Soils; Carter, M.R., Stewart, B.A., Eds.; CRC Press: Boca Raton, FL, 1996; 263–307. Tisdall, J.M.; Oades, J.M. Organic matter and waterstable aggregates in soils. J. Soil Sci. 1982, 33, 141–163. Skjemstad, J.O.; Le Feuvre, R.P.; Prebble, R.E. Turnover of soil organic matter under pasture as determined by 13C natural abundance. Aust. J. Soil Res. 1990, 28, 267–276. Buyanovsky, G.A.; Aslam, M.; Wagner, G.H. Carbon turnover in soil physical fractions. Soil Sci. Soc. Am. J. 1994, 58, 1167–1173. Monreal, C.M.; Schulten, H.R.; Kodama, H. Age, turnover and molecular diversity of soil organic matter in aggregates of a gleysol. Can. J. Soil Sci. 1997, 77, 379–388. Angers, D.A.; Giroux, M. Recently deposited organic matter in soil water-stable aggregates. Soil Sci. Soc. Am. J. 1996, 60, 1547–1551. Six, J.; Elliott, E.T.; Paustian, K. Aggregate and soil organic matter dynamics under conventional and no-tillage systems. Soil Sci. Soc. Am. J. 1999, 63, 1350–1358.
Organic Matter: Global Distribution in World Ecosystems Wilfred M. Post Oak Ridge National Laboratory, Oak Ridge, Tennessee, U.S.A.
INTRODUCTION Globally, the amount of organic matter in soils, commonly represented by the mass of carbon, is estimated to be 1200–1500 Pg C (1 Pg C ¼ 1015 g carbon) in the top 1 m of soil.[1,2] This is 2–3 times larger than the amount of organic matter in living organisms in all terrestrial ecosystems.[1] The exact ratio between living and dead organic matter in terrestrial ecosystems varies, depending on the ecosystem. The amount of carbon stored in soil is determined by the balance of two biotic processes—the productivity of terrestrial vegetation and the decomposition of organic matter. Each of these processes has strong physical and biological controlling factors. These include climate; soil chemical, physical, and biological properties; and vegetation composition. Interactions among these controlling factors are of particular importance. These biological and physical factors are the same as the ones that influence the above ground structure and composition of terrestrial ecosystems, so there are strong correspondences between soil organic matter content and ecosystem type.
ORGANIC MATTER INPUTS Quantity The amount of carbon stored in soils is to a great extent determined by the rate of organic matter input through litterfall, root exudates, and root turnover. The main factors that influence vegetation production are suitable temperatures for photosynthesis, available soil moisture for evapotranspiration, and rates of CO2 and H2O exchange. Dry and=or cold climates support low vegetation production rates and soils under such climates have low organic matter contents. Where climates are warm and moist, vegetation production is high and soil organic matter contents are correspondingly high. Fig. 1 shows the striking correspondence between soil organic matter content and general climate measurements that results from the relationship between vegetation production and suitable moisture and temperature conditions. Vegetation production depends not only on climate but also on nutrient supply from decomposition and 1216 Copyright © 2006 by Taylor & Francis
geochemical weathering. Walker and Adams[6] hypothesized that the level of available phosphorus during the course of soil development is the primary determinant of terrestrial net primary production. Numerous workers have examined this hypothesis. Tiessen, Stewart, and Cole[7] and Roberts, Stewart, and Bettany[8] found that available phosphorus explained about one-fourth of the variance in soil organic matter in many different soil orders. The relationship between phosphorus and carbon is strongest during the aggrading stage of vegetation–soil system development.[9] Initially, the production of acidic products by pioneer vegetation promotes the release of phosphorus by weathering of parent material. Organic matter builds up in the soil, increasing the storage of phosphorus in decomposing organic compounds. Nitrogen fixing bacteria populations, which depend on a supply of organic carbon and available phosphorus, can grow to meet ecosystem demands for nitrogen. Plant growth is enhanced by this increasing nitrogen and phosphorus cycling, resulting in increased rates of weathering. This process continues until the vegetation is constrained by other factors affecting phosphorus availability: Leaching losses become larger than the weathering inputs;[10] or an increasing fraction of the phosphorus becomes unavailable by adsorption or precipitation with secondary minerals;[11] or nitrogen availability (denitrification or leaching is affected) reaching or exceeding nitrogen inputs and fixation.[12] In mature soils, net primary production is more likely to be limited by nitrogen. Availability of other nutrients that are largely derived from parent materials, such as most base cations, may also influence soil organic matter accumulation during early soil development.[13] Soils derived from base cation rich volcanic parent materials (Andisols) have much higher carbon contents on average than soils from other parent materials.[4] Species Composition Biotic factors, in particular plant species composition, also affect soil organic matter dynamics. Production and decomposition rates are to some degree controlled by species composition. Each terrestrial plant species produces different amounts and chemical compositions of leaves, roots, branches, and wood of varying decomposability. This range of decomposability may be Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001792 Copyright # 2006 by Taylor & Francis. All rights reserved.
Organic Matter: Global Distribution in World Ecosystems
1217
Fig. 1 Contours of soil carbon density (kg m2) plotted on Holdridge diagram[3] for world life-zone classification. Values of biotemperature and precipitation uniquely determine a life zone and associated vegetation. Contour lines for mean soil carbon content in the surface meter of soil are determined from data derived from over 3000 soil profiles.[4,5]
summarized by the lignin and nitrogen content of the organic material.[14,15] Litter decay rate is inversely related to C : N and lignin:N ratios and positively related to N content. Species with tissues that have low nutrient or high lignin content produce litter that is slow to decay. Nitrogen is made available to plants during the decomposition process. Nitrogen is a limiting element for productivity in most terrestrial ecosystems so the rate at which it is released during decomposition is an important factor in ecosystem production. Thus, the interactions between processes regulating plant populations and their productivity and microbial processes regulating nitrogen availability result in some of the observed variation in soil carbon and nitrogen storage.[16–19]
Placement The deeper that fresh detritus is placed in the soil, the slower it decomposes. This is a result of declining
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decomposer activity and increased protection from oxidation with depth in the soil. Prairies have a somewhat lower productivity than forests and produce no slowly decomposing woody material. Nevertheless, prairies have a very high soil organic matter content because prairie grasses allocate twice as much production to belowground roots and tillers than to aboveground leaves.[20] The result is high soil organic matter contents with a uniform distribution in the upper 1 m of soil (Fig. 2). In contrast, a spruce–fir forest contains 50 percent of its soil organic matter in the top 10 cm. There are interesting exceptions to the rule that above-=belowground plant allocation determines soil organic matter distribution patterns in soil. Tropical moist forest soils show a uniform depth distribution similar to the depth distribution of temperate grasslands, however, in tropical forests this is largely due to a long-term accumulation of recalcitrant organic materials at lower depths in the soil rather than increased allocation to roots. Alpine tundra soils support a largely herbaceous flora but show a similar
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Organic Matter: Global Distribution in World Ecosystems
and as precipitation increases in the warm temperate, subtropical, and tropical life zones. The combined influence of temperature and precipitation is presented by the third axis of the Holdridge diagram (Fig. 1) as the ratio of potential evapotranspiration (PET) to annual precipitation. When this ratio is less than 1.0, rainfall exceeds PET and vice versa. Life zones bordering the line with the PET is equal to precipitation (PET ratio ¼ 1.0) have soil carbon contents around 10 kg m2 except in warm temperate and subtropical zones where strong seasonality limits production, but decomposition conditions are favorable for most of the year. Soil carbon content increases as the PET ratio decreases indicating that productivity increases faster than the rate of decomposition with increasing moisture availability.
Organic Matter Quality
Fig. 2 Cumulative carbon storage as a function of depth for four ecosystems. Refer text for explanation of these patterns. (From Ref.[4].)
depth distribution as forest soils because of inhibition of surface litter decomposition by low temperatures and high water saturation.
DECOMPOSITION Climate Organic matter decay rates can be related to environmental parameters such as temperature and soil moisture. Climatic indices that correlate well with decay rates include plant moisture and temperature indices,[21,22] linear combinations of temperature and rainfall,[23] and actual evapotranspiration.[15] Warm temperatures and available soil moisture enhance microbial, and micro- and macro-invertebrate activity. These environmental conditions are also correlated with plant production. As a result, the amount of organic matter present in soil is highest in vegetation types with the highest rates of organic matter production. These are ones found in the warm, moist climate regions. The contours of soil carbon density displayed in Fig. 1 reflect the balance of input by vegetation production and loss from decomposition imposed by climate. Soil carbon content increases from lower left to the upper right in Fig. 1 as the temperature decreases in the cool temperate, boreal, and sub-polar life zones
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On global scale, climate may be the most important factor controlling decay rates, but within a given region, substrate chemistry is the more important factor.[15,24,25] Decay rate is often negatively related to substrate C : N ratio. Litter C : N is initially much greater than microbial C : N but approaches microbial C : N as the microbes release the carbon as CO2 while taking up nitrogen (nitrogen immobilization). The further the initial litter C : N is from microbial C : N, the slower the decay rate. Lignin content or lignin: N ratios may be better predictors of decay rates because lignin itself is difficult to decompose, and it shields nitrogen and other more easily degraded chemical fractions from microbes. Concise and simple models of decay rate are based on a combination of chemical and climatic indices. The effect of litter quality on soil organic matter content is most dramatically expressed in Podzols (Spodosol in the United States Department of Agriculture classification). These occur over large areas in boreal zones dominated by evergreen conifers, but often occur in other regions on shallow or sandy soils. Low nitrogen content of organic matter inputs and cool temperatures reduce decomposition and soil animal activity. As a result, large surface organic matter accumulations occur over a thin A horizon. Low temperatures combined with leaching of organic acids result in podsolization as the predominant soil-forming process. Leaching of iron, aluminum oxides, and organic matter result in a distinct E horizon near the surface where these materials are removed and deposited in the B horizon. If the surface organic layers are included, these soils can have substantial organic matter contents, exceeding the expected amount for the climate conditions. Batjes[2] gives an average value for Podzols of 24.2 kg m2 for the surface meter which is
Organic Matter: Global Distribution in World Ecosystems
Table 1 Mean organic carbon contents (kg m2) by FAO–UNESCO soil units to 1 m depth Soil unit
Mean C (kg m2)
Acrisols
9.4
Cambisols
9.6
Chernozems Podzoluvisols
12.5 7.3
Ferrasols
10.7
Gleysols
13.1
Phaeozems
14.6
Fluvisols
9.3
Kastanozems
9.6
Luvisols
6.5
Greyzems
19.7
Nitosols
8.4
Histosols
77.6
Podzols
24.2
Arenosols
3.1
Regosols
5.0
Solonetz
6.2
Andisols
25.4
Vertisols
11.1
Planosols
7.7
Xerosols
4.8
Yermosols
3.0
Solochaks
4.2
These soil units generally span a wide range of climate conditions and therefore present a different view of soil organic matter content based on additional soil factors. In particular, the high C content of Podzols, Histosols, and Andisols is apparent. Refer text for additional explanation of biological, chemical and physical factors responsible. (From Ref.[2].)
considerably above the mean for most other soil types (see Table 1). SIGNIFICANT PHYSICAL AND CHEMICAL INFLUENCES There are several notable exceptions to the climatebased explanation of variation in soil carbon content. There are two in particular that have lower rates of decomposition and therefore higher accumulations of organic matter than expected (Table 1). These include Histosols due to hydrological conditions and Andisols due to parent material chemical effects. Histosols In landscape positions where water accumulates at or above the surface of the soil for an appreciable part
Copyright © 2006 by Taylor & Francis
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of the growing season, decomposition can be reduced to such an extent that large amounts of undecomposed organic matter can accumulate. This soil type is called a Histosol and can be found in any region in wetlands where decomposition is restricted. The soil-surface of mature or old-growth boreal forests over shallow water tables are often covered with Sphagnum moss which may also lead to development of Histosols. Histosols with the largest areas and thickest accumulations occur in lowland tundra where a mixture of sedges, lichens, and mosses grow at the northern limit of vegetation in the northern hemisphere. Production, decomposition, and evaporation are limited by low temperatures and water-saturated soils. In these cold regions, deeper layers may freeze and and not become thawed during the short growing season (permafrost). As a result, Histosols have carbon contents over 70 kg m2 in the surface meter (Table 1). Some regions have been accumulating organic matter since the last glacial period without any substantial decomposition. Histosols in such regions may be several meters thick and contain over 250 kg C m2.[2] Globally it is estimated that boreal and sub-arctic Histosols contain 455 PgC that has accumulated during the postglacial period.[26] Andisols Andisols form on young volcanic stone (basalt lava) rich in nutrients and alkaline. Andisols are weakly weathered soils associated with pyroclastic parent materials that are rich in allophane, ferrihydrite, and other minerals that readily form complexes with humus molecules. These chemical constituents provide conditions promoting high vegetation production and also the retention of organic matter in soil. As a result, Andisols typically have higher soil carbon contents (25.4 kg m2, Table 1) than soils with the same environmental conditions but different parent materials.
CONCLUSIONS Over long periods of time, organic matter in soils is the result of climatic, biological, and geological factors. These factors are not independent. In particular there exists a strong relationship between climate and vegetation type. In Fig. 1, the Holdridge climate based life zones have names that depict the dominant vegetation of climates. Jobba´gy and Jackson[27] provide a summary of soil data based on biomes that demonstrates similar soil carbon distribution as that based on climate (Table 2). Over shorter periods of time soil carbon varies with vegetation disturbances and changes in land use
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Organic Matter: Global Distribution in World Ecosystems
Table 2 Mean organic carbon content (kg m2) by biome to 1 m depth Biome Boreal forest
Mean C (kg m2) 9.3
Crops
11.2
Deserts
6.2
Sclerophyllous shrubs
8.9
Temperate deciduous forest
17.4
Temperate evergreen forest
14.5
Temperate grassland
11.7
Tropical deciduous forest
15.8
Tropical evergreen forest
18.6
Tropical grassland=savanna
13.2
Tundra
14.2
Biome classification is based on Whittaker.[28] (From Ref.[27].)
patterns that affect rates of organic matter input and its decomposition. Various land uses result in very rapid declines in soil organic matter from the native condition.[29–32] Losses of 50% in the top 20 cm and 30% for the surface 100 cm are average. Much of this loss in soil organic carbon can be attributed to erosion, reduced inputs of organic matter, increased decomposability of crop residues, and tillage effects that decrease the amount of physical protection to decomposition. Evidence from long-term experiments suggest that C losses due to oxidation and erosion can be reversed with soil management practices that minimize soil disturbance and optimize plant yield through fertilization. These experimental results are believed to apply to large regions and that organic matter is being restored as a result of establishment of perennial vegetation, increased adoption of conservation tillage methods, efficient use of fertilizers, and increased use of high yielding crop varieties.[33,34] Additionally, when agricultural land is no longer used for cultivation and allowed to revert to natural vegetation or replanted to perennial vegetation, soil organic carbon can accumulate by processes that essentially reversing some of the effects responsible for soil organic carbon losses initially—from when the land was converted from perennial vegetation—and return them to typical amounts for the climate, vegetation, landscape position, and parent material conditions.[35,36]
ACKNOWLEDGMENTS Work sponsored by U.S. Department of Energy, Carbon Dioxide Research Program, Environmental Sciences Division, Office of Biological and Environmental Research and performed at Oak Ridge
Copyright © 2006 by Taylor & Francis
National Laboratory (ORNL). ORNL is managed by UT-Battelle, LLC, for the U.S. Department of Energy under contract DE-AC05-00OR22725.
REFERENCES 1. Post, W.M.; Peng, T.-H.; Emanuel, W.R.; King, A.W.; Dale, V.H.; DeAngelis, D.L. The global carbon cycle. American Scientist 1990, 78, 310–326. 2. Batjes, N.H. Total carbon and nitrogen in the soils of the world. European Journal of Soil Science 1996, 47, 151–163. 3. Holdridge, L.R. Determination of world plant formations from simple climatic data. Science 1947, 105, 367–368. 4. Zinke, P.J.; Stangenberger, A.G.; Post, W.M.; Emanuel, W.R.; Olson, J.S. Worldwide Organic Soil Carbon and Nitrogen Data; ORNL=TM-8857; Oak Ridge National Laboratory: Oak Ridge, TN, 1984. 5. Post, W.M.; Pastor, J.; Zinke, P.J.; Stangenberger, A.G. Global patterns of soil nitrogen storage. Nature 1985, 317, 613–616. 6. Walker, T.W.; Adams, A.F.R. Studies on soil organic matter: I. Influence of phosphorus content of parent materials on accumulations of carbon, nitrogen, sulfur, and organic phosphorus in grassland soils. Soil Science 1958, 85, 307–318. 7. Tiessen, H.J.; Stewart, W.B.; Cole, C.V. Pathways of phosphorus transformations in soils of differing pedogenesis. Soil Science Society of America Journal 1984, 48, 853–858. 8. Roberts, T.L.; Stewart, J.W.B.; Bettany, J.R. The influence of topography on the distribution of organic and inorganic soil phosphorus across a narrow environmental gradient. Canadian Journal of Soil Science 1985, 65, 651–665. 9. Anderson, D.W. The effect of parent material and soil development on nutrient cycling in temperate ecosystems. Biogeochemistry 1988, 5, 71–97. 10. Jenny, H. The Soil Resource; Springer: Berlin, 1980. 11. Walker, T.W.; Syers, J.K. The fate of phosphorus during pedogenesis. Geoderma 1976, 15, 1–19. 12. Schlesinger, W.H. Biogeochemistry: An Analysis of Global Change; Academic: New York, 1991. 13. Torn, M.S.; Trumbore, S.E.; Chadwick, O.A.; Vitousek, P.M.; Hendricks, D.M. Mineral control of soil organic carbon storage and turnover. Nature 1997, 389, 170–173. 14. Aber, J.D.; Melillo, J.M. Nitrogen immobilization in decaying hardwood leaf litter as a function of initial nitrogen and lignin content. Canadian Journal of Botany 1982, 58, 416–421. 15. Meentemeyer, V. Macroclimate and lignin control oflitter decomposition rates. Ecology 1978, 59, 465–472. 16. Zinke, P.J. The pattern of influence of individual trees on soil properties. Ecology 1962, 42, 130–133. 17. Wedin, D.A.; Tilman, D. Species effects on nitrogen cycling: a test with perennial grasses. Oecologia 1990, 84, 433–441.
Organic Matter: Global Distribution in World Ecosystems
18. Hobbie, S.E. Effects of plant species on nutrient cycling. Trends in Ecology and Evolution 1992, 7, 336–339. 19. Hobbie, S.E. Temperature and plant species control over litter decomposition in Alaskan tundra. Ecological Monographs 1996, 66, 503–522. 20. Sims, P.L.; Coupland, R.T. Grassland Ecosystems of the World: Analysis of Grasslands and Their Uses; Coupland, R.T., Ed.; Cambridge University Press: Cambridge, 1979. 21. Olson, J.S. Energy storage and the balance of producers and decomposers in ecological systems. Ecology 1963, 44, 322–331. 22. Fogel, R.; Cromack, K. Effect of habitat and substrate quality on douglas fir litter decomposition in western Oregon. Canadian Journal of Botany 1977, 55, 1632–1640. 23. Pandey, V.; Singh, J.S. Leaf-litter decomposition in an oak–conifer forest in himalaya: the effects of climate and chemical composition. Forestry 1982, 55, 47–59. 24. Flanagan, P.W.; VanCleve, K. Nutrient cycling in relation to decomposition and organic matter quality in tiaga ecosystems. Canadian Journal of Forest Research 1983, 13, 795–817. 25. McClaugherty, C.A.; Pastor, J.; Aber, J.D.; Melillo, J.M. Forest litter decomposition in relation to soil nitrogen dynamics and litter quality. Ecology 1984, 66, 266–275. 26. Gorham, E. Northern peatlands: role in the carbon cycle and probable responses to climatic warming. Ecological Applications 1991, 1, 182–195.
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27. Jobba´gy, E.G.; Jackson, R.B. The vertical distribution of organic carbon and its relation to climate and vegetation. Ecological Applications 2000, 10 (2), 423–436. 28. Whittaker, R.H. Communities and Ecosystems; MacMillan: London, 1975. 29. Jenny, H. Factors of Soil Formation; McGraw-Hill: New York, 1941. 30. Davidson, E.A.; Ackerman, I.L. Changes in soil carbon inventories following cultivation of previously untilled soils. Biogeochemistry 1993, 20, 161–193. 31. Mann, L.K. Changes in soil carbon after cultivation. Soil Science 1986, 142, 279–288. 32. Schlesinger, W.H. Changes in soil carbon storage and associated properties with disturbance and recovery. In The Changing Carbon Cycle: A Global Analysis; Trabalka, J.R., Reichle, D.E., Eds.; Springer: New York, 1985. 33. Buyanovsky, G.A.; Wagner, G.H. Carbon cycling in cultivated land and its global significance. Global Change Biology 1998, 4, 131–142. 34. Lal, R.; Kimble, J.M.; Follett, R.F.; Cole, C.V. The Potential of U.S. Cropland to Sequester Carbon and Mitigate the Greenhouse Effect; Ann Arbor Press: Ann Arbor, 1998. 35. Post, W.M.; Kwon, K.C. Soil carbon sequestration and land-use change: processes and potential. Global Change Biology 2000, 6, 317–328. 36. Silver, W.L.; Ostertag, R.; Lugo, A.E. The potential for carbon sequestration through reforestation of abandoned tropical agricultural and pasture lands. Restoration Ecology 2000, 8 (4), 394–407.
Organisms and Soil Food Webs David C. Coleman University of Georgia, Athens, Georgia, U.S.A.
INTRODUCTION Soils may be viewed as the organizing centers for terrestrial ecosystems. This is largely the result of organismal activities in the soil. Major functions such as ecosystem production, respiration and nutrient recycling are controlled by the rates at which nutrients are released by decomposition in the soil and litter horizons. The array of biota, including microbes, microbe-feeding fauna, vegetation, and consumers are all influenced by soil processes, and the organisms in turn have an impact on the soil system. Soils provide a wide range and variety of microhabitats, thus accommodating a very diverse biota. The enormous surface area (hundreds of m2=g of soil) of soil particles, ranges in size classes from clays (0.1– 2 mm in dia), to silts (2–50 mm in dia), and sands (0.05–2 mm in dia). Numerous microbes and microand mesofauna (protozoa and nematodes) exist in water films on these particles, and in or on the surfaces of microaggregates formed from the primary particles.[1] In turn, the more mobile fauna, from collembola and mites (larger mesofauna) to the macrofauna (earthworms, millipedes, ants, termites, and fossorial or earth-dwelling vertebrates) move through macroand micropores in the soil. The macrofauna plays a role in moving parts of the soil profile around, and form many sorts of burrows and pores; they are often termed ‘‘ecological engineers.’’
relationships have several trophic levels, with bacteria and fungi being fed upon by microbe-feeders, such as protozoa, nematodes and microarthropods, which are in turn preyed upon by predatory nematodes or mites, and these in turn fed upon by higher predators (Fig. 1). In forests or no tillage agroecosystems, where fungi dominate in the surface litter, the dominant flows of energy and nutrients will go via fungal pathways. In contrast, in conventional tilled fields where the organic matter is incorporated in the plow layer (usually 6–8 in. ¼ 15–20 cm), the dominant flows of energy and nutrients may be more bacterially dominated, usually decomposing faster than in the no tillage system.[1]
ZONES OF INFLUENCE The heterogeneous distribution of food resources in the soil matrix makes it difficult to sample adequately for abundances and activities of the biota in a repeatable fashion. A useful approach is to consider soils as being comprised of zones of influence (ZOI), that can be targeted for further study. These ZOI, also termed ‘‘hot spots,’’ are located in the root-rhizosphere, in regions of organic detritus accumulation, or detritusphere, and also in earthworm-influenced regions, such as burrows, which are termed a drilosphere[4] (Fig. 2). These ZOI may represent less than 10% of the volume of the surface A horizon, but account for up to 90% of the total biological activity in soils worldwide.
SOIL FOOD WEBS The initial breaking up or ‘‘comminution,’’ of plant litter (above- and below-ground) results from the chewing and macerating action of both large and small animals. This comminution benefits the fauna, which derive nutritional benefit from the litter and= or microbes initially colonizing the plant material. The increased surface area and further inoculation of the smaller pieces enhances the microbial access to, and breakdown of, these tissues. The decomposition process drives complex food webs[2,3] in the soil, with numerous interactions between the initial agents of decomposition, the bacteria and fungi, and the fauna that in turn feed upon them, which facilitates nutrient return in the soil matrix (Fig. 1). These feeding 1222 Copyright © 2006 by Taylor & Francis
ROLES OF BIOTA IN SOIL FOOD WEBS The functional roles of soil organisms can be compared most usefully in terms of body width. The microbes and microfauna inhabit soil water films, and are restricted to this aquatic milieu. In contrast, the mesoand macrofauna, from acari (mites) to earthworms, inhabit gas-filled pores, and move around in the soil matrix for considerable distances (Fig. 3).[5] Bacteria Bacteria are unicellular prokaryotes (organisms lacking a unit membrane-bounded nucleus and other Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001817 Copyright # 2006 by Taylor & Francis. All rights reserved.
Organisms and Soil Food Webs
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Fig. 1 Representation of detrital food web in shortgrass prairie. Fungal-feeding mites are separated into two groups (I and II) to distinguish the slow-growing oribatids from faster-growing taxa. Flows omitted from the figure for the sake of clarity include transfers from every organism to the substrate pools (death) and transfers from every animal to the substrate pools (defecation) and to inorganic N (ammonification). (From Ref.[2].)
organelles), that are found in all habitats on earth. They are exceedingly numerous (more than 1030, or one million trillion trillion[6]) and diverse, currently comprising over 35 kingdoms in two domains, the Archaea and Eubacteria. They are active in all aspects of elemental cycling, and needed for nitrogen cycling, both in nitrogen fixation (splitting N2 and incorporating N into organic compounds), and subsequent transformational pathways as well. They are also primary agents of decomposition in many habitats, and are particularly active in rhizospheres.[4]
decomposed subunits, and translocating them back through the hyphal network. Fungi are very abundant, particularly in undisturbed forest floors, in which literally thousands of kilometers of hyphal filaments will occur per gram of leaf litter. The roles of mycorrhizas (literally ‘‘fungus–root,’’ or symbiotic fungi associated with many plants) in soil systems are being increasingly viewed as central to much of terrestrial ecosystem function. Mycorrhizas are essential to the growth and reproduction of numerous families of plants.[1]
Fungi
Microfauna
Fungi are multicellular eukaryotes that are found in many habitats worldwide. They have long, ramifying strands (hyphae) which can grow into and explore many microhabitats, and are used for obtaining water and nutrients. The hyphae secrete a considerable array of enzymes, such as cellulases, and even lignases in some specialized forms (useful in breaking down wood), decomposing substrates in situ, taking up the
The unicellular eukaryotes, or Protoctista, are more often called protozoans. They include the flagellates, naked amoebae, testacea, and ciliates. These organisms range in size from a few cubic micrometers in volume (micro flagellates) to larger ciliates, which may be up to 500 mm in length and 20–30 mm in width. Protozoa are abundant, reaching densities of from 100 to 200 thousand per gram of soil. Bacteria, their principal
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Organisms and Soil Food Webs
Fig. 2 Areas of activity in soil systems. These ‘‘ZOI’’ may be 90% of the total biological activity in most soils worldwide. (From Ref.[4].)
prey, often exist in numbers up to one billion per gram of soil. All of these organisms are true water-film dwellers, and become dormant or inactive during episodes of drying in the soil. They can exist in inactive or resting stages literally for decades at a time in very xeric environments. Mesofauna Nematodes Nematodes have a wide range of feeding preferences. A general trophic grouping is bacterial feeders, fungal feeders, plant feeders, and predators and omnivores. Anterior (stomal or mouth) structures can be used to differentiate general feeding or trophic groups. Because nematodes reflect the developmental stages of the systems in which they occur (e.g., annual vs.
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perennial crops, or old fields and pastures and more mature forests), they have been used as indicators of overall ecosystem condition.[7,8] Collembola Collembolans, or ‘‘springtails’’ are primitive apterygote (wingless) insects. They are called ‘‘springtails’’ because many of them have a spring-like lever, or furcula, which enables them to move many body-lengths away from predators in a springing fashion. Collembolans are ubiquitous members of the soil fauna, often reaching abundances on 100,000 or more per m2. They occur throughout the soil profile, where their major diet is decaying vegetation and associated microbes (usually fungi). However, like many members of the soil fauna, collembolans defy placement in exact trophic groups. Many collembolan species will eat
Organisms and Soil Food Webs
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Fig. 3 Size classification of organisms in decomposer food webs by body width. (From Ref.[5].)
nematodes when those are abundant. Some feed on live plants or their roots. One family (Onychiuridae) may feed in the rhizosphere and consume mycorrhizas or even plant pathogenic fungi.[9]
sources and are rare except in agricultural soils. The Prostigmata contains a broad diversity of mites with several feeding habits.[1]
Macrofauna Mites (Acari) The soil mites, Acari, are chelicerate arthropods related to the spiders. They are often the most abundant microarthropods in soils. A 100 g sample may contain as many as 500 mites representing nearly 100 genera. This diverse array includes participants in three or more trophic levels, with varied strategies for feeding, reproduction, and dispersal. The oribatid mites (Oribatei) are the characteristic mites of the soil and are usually fungivorous or detritivorous. Mesostigmatid mites are nearly all predators on other small fauna, although a few species are fungivores and may become numerous at times. Astigmatid mites are associated with rich, decomposing nitrogen
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Termites (Isoptera) are one of the major ecosystem ‘‘engineers,’’ particularly in tropical regions. Termites are social insects with a well-developed caste system. By their ability to digest wood, they have become economic pests of major importance in some regions of the world. The termites in a primitive family, the Kalotermitidae, possess a gut flora of protozoans, which enables them to digest cellulose. Their normal food is wood that has come into contact with soil. Many species of termites construct runways of soil, or along root channels, and some are builders of large, spectacular mounds. Members of the phylogenetically advanced family Termitidae possess a formidable array of microbial symbionts (bacteria and fungi, but not protozoa),
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and elevated pH in their hindguts,[10] which enable them to process and digest the humified organic matter in tropical soils and to thrive on it. Termites parallel earthworms in ingestive and soil turnover functions. The principal difference is that earthworms egest much of what they ingest in altered form (that enriches microbial action), whereas termites transfer large amounts of soil (organic material into building nests and mounds (carbon sinks).
Earthworms Much of the evidence for earthworm effects on soil processes comes from agroecosystems and involves a small group of European lumbricids (Lumbricidae family in the Oligochaeta order). Impacts of exotic earthworms on native species are not well understood, although there is evidence that when native habitat is destroyed and native earthworm species extirpated, exotic earthworms colonize the newly empty habitat. As more extensive studies are carried out, it is becoming clear that earthworms are present in a wide variety of tropical as well as temperate ecosystems. Earthworms have important roles in the fragmentation, breakdown and incorporation of soil organic matter (SOM). This affects the distribution of SOM, and also its chemical and physical characteristics. Changes in any of these soil parameters may have significant effects on other soil biota, by changing their resource base (e.g., distribution and quality of SOM, microbes or microarthropods) or by changing the physical structure of the soil.[11] Earthworm activities impact the communities of other soil biota through their effects on the chemical and physical characteristics of SOM, causing changes in the microbial and microarthropod communities, and also having impacts elsewhere in the soil food web.[12]
CONCLUSIONS Soil biota are very interconnected with each other by a variety of trophic and nutrient-flow pathways. The possibility of enhancing biotic activity in agricultural systems via conservation or no tillage regimes is very great, and much research is now focusing on this area of interest. This approach permits a melding of
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Organisms and Soil Food Webs
interests between those who want to reduce fossil fuel inputs to agroecosystems and those who are concerned with enhancing carbon sequestration in soils as well.
REFERENCES 1. Coleman, D.C.; Crossley, D.A., Jr. Fundamentals of Soil Ecology; Academic Press: San Diego, CA, 1996; 205. 2. Hunt, H.W.; Coleman, D.C.; Ingham, E.R.; Ingham, R.E.; Elliott, E.T.; Moore, J.C.; Rose, S.L.; Reid, C.P.P.; Morley, C.R. The detrital food web in a shortgrass prairie. Biol. Fert. Soils 1987, 3, 57–68. 3. Moore, J.C.; de Ruiter, P.C. Invertebrates in detrital food webs along gradients of productivity. In Invertebrates as Webmasters in Ecosystems; Coleman, D.C., Hendrix, P.F., Eds.; CABI: Wallingford, UK, 2000; 161–184. 4. Beare, M.H.; Coleman, D.C.; Crossley, D.A., Jr.; Hendrix, P.F.; Odum, E.P. A hierarchical approach to evaluating the significance of soil biodiversity to biogeochemical cycling. Plant Soil 1995, 170, 5–22. 5. Swift, M.J.; Heal, O.W.; Anderson, J.M. Decomposition in Terrestrial Ecosystems; Univ. of California Press: Berkeley, CA, 1979; 379. 6. Whitman, W.B.; Coleman, D.C.; Wiebe, W.J. Prokaryotes: the unseen majority. Proc. Natl. Acad. Sci. 1998, 95, 6578–6583. 7. Bongers, T. The maturity index: an ecological measure of environmental disturbance based on nematode species composition. Oecologia 1990, 83, 14–19. 8. Yeates, G.W.; Bongers, T.; de Goede, R.G.M.; Freckman, D.W.; Georgieva, S.S. Feeding habits in soil nematode families and genera—an outline for soil ecologists. J. Nematol. 1993, 25, 315–331. 9. Lartey, R.T.; Curl, E.A.; Peterson, C.M. Interactions of mycophagous collembola and biological control fungi in the suppression of Rhizoctonia Solani. Soil Biol. Biochem. 1994, 26, 81–88. 10. Bignell, D.E.; Eggleton, P. On the elevated intestinal pH of higher termites (isoptera termitidae). Insectes Sociaux 1995, 42, 57–69. 11. Hendrix, P.F., Ed.; Earthworm Ecology and Biogeography in North America; Lewis Publishers: Boca Raton, FL, 1995; 335. 12. Fu, S.; Cabrera, M.L.; Coleman, D.C.; Kisselle, K.W.; Garrett, C.J.; Hendrix, P.F.; Crossley, D.A., Jr. Soil carbon dynamics of conventional tillage and no-till agroecosystems at Georgia Piedmont—HSB-C models. Ecol. Model. 2000, 131, 229–248.
Organo-Mineral Relationships Claire Chenu Alain F. Plante Unite´ de Science du Sol, INRA-Versailles, Versailles, France
Pascale Puget ESITPA, Rouen, France
INTRODUCTION Organo-mineral relationships are a fundamental feature of soils and are often used to define and differentiate soils from geological parent materials. Soil is primarily a mineral matrix (except in organic soils such as bog peat), but receives inputs of organic materials from various natural sources such as litterfall, root exudates, or from various anthropogenic sources such as manure additions. Organo-mineral relationships range in degree of association from the spatial distribution of particulate organic matter and mineral particles with minimal interaction to the inseparable organic matter intercalated between clay layers. Here, the term association is used to describe an arrangement of organic matter and minerals that has an undefined degree of cohesion. The term complex is restricted to cases where adsorption is the dominant mechanism. Organo-mineral associations cover a wide range of spatial scales, from nanometric (e.g., the complex of an organic acid with a clay sheet) to decimetric (e.g., a soil ped); however, they all originate at the molecular scale where physico-chemical interactions lead to the formation of bonds. The formation of organo-mineral associations may require only minutes, but their lifetime is related to that of the organic component, which can be short or extend to thousands of years. The impact of organo-mineral complexes in soils is significant; 40–80% of soil carbon is present in clay-sized separates and cannot be separated easily from clay minerals.[1] Their importance is also qualitative and functional because the formation of organo-mineral complexes in soils strongly impacts the properties of the mineral phase and influences the biodegradation of organic matter.
CHARACTERIZATION OF ORGANO-MINERAL RELATIONSHIPS Historically, organic matter has been studied by methods that involved their solubilization and separation from soil minerals. On the other hand, mineralogists Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120006622 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
analyzed soil minerals after comprehensive destruction of organic matter with H2O2. Therefore, most of the past knowledge concerning organo-mineral associations was gained from studies performed on synthetic organomineral complexes, prepared from well-defined constituents such as clay minerals from geological deposits and pure organic compounds (e.g., polysaccharides, proteins).[2] Physical methods for soil fractionation such as size or density separation now enable the separation of intact organo-mineral associations from soils and their direct study with a wide range of nondestructive methods such as nuclear magnetic resonance spectroscopy.[3] Primary organo-mineral associations are associations of organic matter with individual soil mineral particles.[4] Their separation requires complete dispersion of soil using mechanical means and size or density separation techniques. Secondary organo-mineral associations, namely aggregates, are made by grouping together of several primary organo-mineral associations. Secondary organo-mineral associations are normally isolated from soil by sieving techniques after mild soil dispersion (e.g., a simple immersion of soil sample in water and agitation).[5] In primary organo-mineral associations, more organic matter is more closely associated with minerals as particle size decreases: sand-sized organic matter (i.e., decomposing plant debris) is separated easily from sand-sized minerals by densimetric techniques,[6,7] whereas little free mineral or organic matter seem to occur in the clay-sized fraction.[8] A variety of compounds are involved in primary organo-mineral associations. The clay-sized associations consist of highly processed and humified compounds, as well as microorganisms and their metabolites.[1,4,9] Clay– organic matter associations also show diverse microstructures, from organic interlayer complexes[10,11] and organic coatings on clay minerals surfaces to more complex structures such as microaggregates of bacteria or plant debris with clay particles (Fig. 1).[12,13] In various soil types and management contexts, secondary organo-mineral complexes are hierarchical: particles associate into microaggregates, which in turn 1227
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Fig. 1 Microstructure of primary organo-mineral associations observed with transmission electron microscopy in clay-sized fractions from soils: (A) complex microaggregate, (B) microaggregate in which OM occurs as layers between stacks of clay. (From Ref.[57].)
associate into larger aggregates.[14–17] The smaller the aggregate hierarchical level, the higher is its physical stability, because the binding agents involved change with the spatial scale. Clay-sized associations are bound by sesquioxides, humic materials, and polysaccharides. These associations are bound into 250 mm by transient agents (e.g., polysaccharides) and temporary ones (e.g., fine roots and fungal hyphae) (Fig. 2).[18,19] Aggregates appear to be formed and stabilized around decomposing plant debris that act as hot spots for microbial activity (Fig. 3).[16,20–23] Binding Forces Within Organo-Mineral Associations A variety of bonds may be formed when organic molecules in solution come into contact with the surface of
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Organo-Mineral Relationships
Fig. 2 Nature and scale of various organo-mineral associations. (From Ref.[18].)
soil minerals (see Fig. 4).[24] For small organic molecules, these interactions depend on their ability to establish electrostatic interactions or dipole interactions. Polarity and polarizability are thus important adsorption-related properties of such organic molecules. For macromolecules, weak interactions such as van der Waals interactions and hydrogen bonding become very important. The conformation of macromolecules largely influences their adsorption, which increases with molecular weight.[2] High-molecularweight polymers are generally adsorbed in an irreversible fashion and therefore the adsorption of macromolecules into soil minerals often leads to the formation of stable organo-mineral complexes. Organic polymers such as polysaccharides, proteins, fulvic, and humic acids are active in the formation of organo-mineral complexes because of their high molecular weight and charge. Similarly, clay minerals are the most active mineral constituents in the formation of organo-mineral complexes because of their charge and their high specific
Organo-Mineral Relationships
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contacts between the organic and mineral surfaces and thus aiding the creation of new bonds.[32,33]
ORGANO-MINERAL RELATIONSHIPS ALTER THE PROPERTIES OF SOIL MINERALS
Fig. 3 Schematic presentation of the interaction between soil organic matter decomposition and aggregate formation and destruction. (Adapted from Refs.[21,22,56].)
surface area.[2] Solid particles, such as bacteria, fungi, or plant debris also establish physico-chemical interactions with mineral surfaces through the process of adhesion. Physico-chemical interactions at the molecular scale (i.e., adsorption and adhesion) provide tensile forces that increase both the tensile strength and the compressive strength of primary as well as secondary organomineral complexes and associations.[25–27] At a larger scale, the binding of aggregates also involves physical mechanisms. Fungal hyphae and fine roots stabilize aggregates by entangling the soil particles[28–30] and thereby increasing aggregate strength through compressive forces. Physical processes, such as those related to shrink–swell or freeze–thaw also alter organomineral associations by (i) creating failure zones that separate aggregates,[14,31] or by (ii) increasing the
Soil properties observed at a macroscopic scale are largely due to changes in the properties and associations of soil primary particles at a microscopic scale, in particular that of clay minerals. For example, the basic physical and physico-chemical mechanisms by which organic matter stabilizes soil aggregates against the disruptive action of water are an increased cohesion of the aggregate or a decreased wettability. Increased cohesion helps the aggregate withstand mechanical disruption by raindrops and resist forces exerted by compressed air upon wetting. Adsorption of large and flexible organic polymers increases the tensile strength of minerals (see above). Decreased wettability of aggregate surfaces slows the rate of wetting of the aggregates and thus the extent of slaking. Synthetic complexes of clays and humic substances, as well as natural complexes, are less wettable than pure clays.[34–36] Associated organic matter also changes the swelling of clays and organo-mineral associations.[37–39] Organo-mineral associations alter the reactivity of soil minerals, particularly of soil clays, thereby altering the retention of cations, trace metals, or organic pollutants in soils. Associated organic matter increases the cation-exchange capacity of soils and soil clays,[40–42] which contributes to the preferential retention of heavy metals by clay-sized fractions of soils. Increased hydrophobicity in the clay fraction, caused by associated organic matter, facilitates the sorption of nonpolar organic pollutants.[43]
Fig. 4 Mechanisms of interaction between clay minerals and organic molecules (From Paul and Clark, 1996).
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ORGANO-MINERAL RELATIONSHIPS REDUCE THE BIODEGRADATION RATE OF ORGANIC MATTER Many easily decomposed compounds are retained in soil for longer periods than expected from their biochemistry. Association of organic matter with soil mineral particles and aggregates usually results in a decrease in the rate of biodegradation of the organic matter. Bartlett and Doner[44] measured the decomposition of two radiolabeled-amino acids in four treatments: in a nonaggregated and nonadsorbed state; in a nonaggregated, but adsorbed state; in an aggregated, but nonadsorbed state; and in an aggregated and adsorbed state. The results showed that decomposition was more rapid in the nonaggregated versus aggregated state, and that adsorption further decreased decomposition. The experiment clearly demonstrates two major mechanisms involved in organic-matter protection: ‘‘chemical protection’’ and ‘‘physical protection.’’[45] Chemical protection refers to the reduced availability to microorganisms (and therefore decomposition) of organic matter in soil due to chemical interactions with soil constituents, such as complexation or adsorption on reactive mineral surfaces. Many natural and contaminant organic compounds are not available to microorganisms when adsorbed.[46–49] Models that best describe the decomposition of compounds in soil couple biodegradation with sorption, and assume that adsorbed compounds are not degraded.[50] While some organisms can access some adsorbed compounds, the rate of decomposition is largely controlled by the desorption of the compound.[50,51] The effect of minerals is also indirect because extracellular enzymes adsorb to clay minerals and become inactivated.[52] The physical protection of organic-matter is the reduction in organic-matter decomposition rates caused by the architecture of the organo-mineral soil matrix. Evidence of physical protection comes primarily from experiments or agronomic situations in which soil structure is disrupted, leading to a flush of mineralization.[53–56] A large proportion of labile soil organic-matter appears to be physically protected in microaggregates.[53] Some degree of contact between a microorganism or extracellular enzyme and the organic substrate is needed to allow biodegradation. Soil microorganisms generally occupy less than 2% of soil surface area and less than 1% of soil porosity.[57] Therefore, large distances can exist between organism and substrate. Soil structure controls the continuity of pores filled with water and their accessibility to microorganisms. Habitable pore space consists of 15–25% of the total porosity, while the remainder is inaccessible to microorganisms because pore necks are smaller that 0.2 mm or pores are air-filled rather
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Organo-Mineral Relationships
than water-filled.[58] Furthermore, soil structure may create sites in which the local physico-chemical conditions are unfavorable to mineralization due to oxygen depletion in anoxic center of aggregates.[59] While the chemical protection provided by adsorption is often permanent, physical protection is highly dynamic. Soil structure is continuously changing due to the action of soil fauna, root growth, wet–dry cycles, and tillage (see Fig. 3). Therefore, physical protection depends on the life expectancy of the arrangement of the protection sites, and is therefore subject to changes due to soil aggregate turnover.[60] While the relative contribution of physical protection to the stabilization of organic matter may be low, it often affords the time for more permanent chemical-protection mechanisms to occur. CONCLUSIONS The existence of ‘‘primary particles’’ and ‘‘clean’’ mineral surfaces in natural soils occurs only rarely (except in the case of sands). Instead, soil is an intimate association of organic matter and mineral surfaces that interact to various degrees. While the binding of organic matter with mineral surfaces occurs at the nano- to micro-meter scale, its impact is felt upwards to the centimeter and meter scales. Organo-mineral relationships are dynamic processes that alter the properties of both the organic matter and mineral particles involved.
REFERENCES 1. Christensen, B.T. Carbon in primary and secondary organo-mineral complexes. In Structure and Organic Matter Storage in Agricultural Soils; Carter, M.R., Stewart, B.A., Eds.; CRC Press Inc.: Boca Raton, FL, 1995; 97–165. 2. Theng, B.K.W. Formation and Properties of Clay– Polymer Complexes; Elsevier Scientific Publishing Company: Amsterdam, 1979. 3. Ko¨gel-Knabner, I. Analytical approaches for characterizing soil organic matter. Org. Geochem. 2000, 31 (7=8), 609–625. 4. Christensen, B.T. Physical fractionation of soil and organic matter in primary particle size and density separates. In Advances in Soil Science; Stewart, B.A., Ed.; Springer: New York, 1992; Vol. 20, 1–90. 5. Elliott, E.T. Aggregate structure and carbon, nitrogen and phosphorus in native and cultivated soils. Soil Sci. Soc. Am. J. 1986, 50 (3), 627–633. 6. Feller, C. Une me´thode de fractionnement granulome´trique de la matie`re organique des sols. Application aux sols tropicaux a` textures grossie`res, tre`s pauvres en humus. Cah. ORSTOM, Se´r. Pe´dologie 1979, XVII, 339–345.
Organo-Mineral Relationships
7. Balesdent, J.; Pe´traud, J.P.; Feller, C. Effet des ultrasons sur la distribution granulome´trique des matie`res organiques des sols. Science Sol. 1991, 29 (2), 95–106. 8. Turchenek, J.M.; Oades, J.M. Fractionation of organomineral complexes by sedimentation and density techniques. Geoderma 1979, 21 (4), 311–343. 9. Oades, J.M. An introduction to organic matter in mineral soils. In Minerals in Soil Environments; Dixon, D.E., Ed.; SSSA Book Series No. 1; Soil Science Society of America: Madison, WI, 1989; 89–158. 10. Theng, B.K.G.; Chuchman, G.J.; Newman, R.H. The occurence of interlayer clay–organic complexes in two New Zealand soils. Soil Sci. 1986, 142 (5), 262–266. 11. Righi, D.; Dinel, H.; Schulten, H.R.; Schnitzer, M. Characterization of clay–organic matter complexes resistant to oxidation by hydrogen peroxide. Eur. J. Soil Sci. 1995, 46 (3), 423–429. 12. Feller, C.; Franc¸ois, C.; Villemin, G.; Portal, J.M.; Toutain, F.; Morel, J.L. Nature des matie`res organiques associe´es aux fractions argileuses d’un sol ferrallitique. C.R. Acad. Sci. Paris. 1991, 312 (12), 1491–1497. 13. Chenu, C.; Arias, M.; Besnard, E. The influence of cultivation on the composition and properties of clay– organic matter associations in soils. In Sustainable Management of Organic Matter; Rees, R.M., Ball, B.C., Campbell, C.D., Watson, C.A., Eds.; CABI International: Wallingford, UK, 2001; 207–213. 14. Dexter, A.R. Advances in characterization of soil structure. Soil Tillage Res. 1988, 11 (3=4), 199–238. 15. Oades, J.M.; Waters, A.G. Aggregate hierarchy in soils. Aust. J. Soil Res. 1991, 29 (6), 815–828. 16. Puget, P.; Chenu, C.; Balesdent, J. Dynamics of soil organic matter associated with primary particle size fractions of water-stable aggregates. Eur. J. Soil Sci. 2000, 51 (4), 595–605. 17. Six, J.; Paustian, K.; Elliott, E.T.; Combrink, C. Soil structure and organic matter: I. Distribution of aggregate-size classes and aggregate-associated carbon. Soil Sci. Soc. Am. J. 2000, 64 (2), 681–689. 18. Tisdall, J.M.; Oades, J.M. Organic matter and waterstable aggregates. J. Soil Sci. 1982, 33 (2), 141–163. 19. Jastrow, J.D.; Miller, R.M.; Lussenhop, J. Contributions of interacting biological mechanisms to soil aggregate stabilization in restored prairie. Soil Biol. Biochem. 1998, 30 (7), 905–916. 20. Beare, M.H.; Hendrix, P.F.; Coleman, D.C. Waterstable aggregates and organic matter fractions in conventional-tillage and no-tillage soils. Soil Sci. Soc. Am. J. 1994, 58 (3), 777–786. 21. Golchin, A.; Oades, J.M.; Skjemstad, J.O.; Clarke, P. Soil structure and carbon cycling. Aust. J. Soil Res. 1994, 32 (5), 1043–1068. 22. Chenu, C.; Puget, P.; Balesdent, J. Clay–Organic Matter Associations in Soils: Microstructure and Contribution to Soil Physical Stability, 16th World Congress of Soil Science, Montpellier, France, Aug 20–26, 1998; Cirad: Montpellier, France, CD-ROM. 23. Golchin, A.; Baldock, J.A.; Oades, J.M. A model linking organic matter decomposition, chemistry, and aggregate dynamics. In Soil Processes and the Carbon Cycle;
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41. Curtin, D.; Rostad, H.P.W. Cation exchange capacity and buffer potential of saskatchewan soils estimated from texture, organic matter and pH. Can. J. Soil Sci. 1997, 77 (4), 621–626. 42. Bigorre, F. Contribution des argiles et des matie`res organiques a` la re´tention d’eau dans les Sols. Significa´ change en tion et ro ^ le fondamental de la capacite´ d’E cations. C.R. Acad. Sci. Paris 1999, 330 (3), 245–250. 43. Wershaw, R.L. A new model for humic materials and their interactions with hydrophobic organic chemicals in soil water or sediment water systems. J. Contaminant Hydrol. 1986, 1 (1/2), 29–45. 44. Bartlett, J.R.; Doner, H.E. Decomposition of lysine and leucine in soil aggregates: adsorption and compartmentalization. Soil Biol. Biochem. 1988, 20 (5), 755–759. 45. Baldock, J.A.; Skjemstad, J.O. Role of the soil matrix and minerals in protecting natural organic materials against biological attack. Org. Geochem. 2000, 31 (7/8), 697–710. 46. Aardema, B.W.; Lorenz, M.G.; Krumbein, W.E. Protection of sediment adsorbed transforming DNA against enzymatic inactivation. Appl. Environ. Microbiol. 1983, 46 (2), 417–420. 47. Ogram, A.; Jessup, R.E.; Ou, L.T.; Rao, P.S.C. Effects of sorption on biological degradation rates of (2,4Dichlorophenoxy) acetic acid in soils. Appl. Environ. Microbiol. 1985, 49 (3), 582–587. 48. Dashman, T.; Stotzky, G. Microbial utilization of amino acids and a peptide bound on homoionic montmorillonite and kaolinite. Soil Biol. Biochem. 1986, 18 (1), 5–14. 49. Jones, D.L.; Edwards, A.C. Influence of sorption on the biological utilization of two simple carbon substrates. Soil Biol. Biochem. 1998, 30 (14), 1895–1902. 50. Scow, K.M.; Johnson, C.R. Effect of sorption on biodegradation of soil pollutants. Adv. Agron. 1997, 58 (1), 1–56. 51. Rao, P.S.C.; Bellin, C.A.; Lee, L.S. Sorption and biodegradation of organic contaminants in soils: conceptual representations of process coupling. In Environmental Impact of Soil Component Interactions: Volume 1:
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Natural and Anthropogenic Organics. Proceedings of a Workshop Entitled ‘Impact of Interactions of Inorganic, Organic and Microbiological Soil Components on Environmental Quality, Edmonton AB, Aug 11–15, 1992; Lewis Publishers: Boca Raton, FL, 1995; 263–274. Quiquampoix, H. Mechanisms of protein adsorption on surfaces and consequences for soil extracellular enzyme activity. In Soil Biochemistry; Bollag, J.M., Stotzky, G., Eds.; Marcel Dekker: New York, 2000; Vol. 10, 171–206. Gregorich, E.G.; Kachanovski, R.G.; Voroney, R.P. Carbon mineralization in soil size fractions after various amounts of aggregate disruption. J. Soil Sci. 1989, 40 (3), 649–659. Balesdent, J.; Boisgontier, D.; Mariotti, A. Effect of tillage on soil organic carbon mineralization estimated from 13C abundance in maize fields. J. Soil Sci. 1990, 41 (4), 587–596. Beare, M.H.; Cabrera, M.L.; Hendrix, P.F.; Coleman, D.C. Aggregate-protected and unprotected organic matter pools in conventional-tillage and no-tillage soils. Soil Sci. Soc. Am. J. 1994, 58 (3), 787–795. Balesdent, J.; Chenu, C.; Balabane, M. Relationship of soil organic matter dynamics to physical protection and tillage. Soil Tillage Res. 2000, 53 (3/4), 215–230. Chenu, C.; Stotzky, G. Interactions between microorganisms and soil particles: an overview. In Interactions Between Microorganisms and Soild Particles in the Soil Environment; Huang, P.M., Ed.; 2002, in press. Hassink, J.; Bouwman, J.; Brussaard, L.B. Relationships between habitable pore space, soil biota and mineralization rates in grassland soils. Soil Biol. Biochem. 1993, 25 (1), 47–55. Sextone, A.J.; Revsbech, N.P.; Parkin, T.B.; Tiedje, J.M. Direct measurement of oxygen profiles and denitrification rates in soil aggregates. Soil Sci. Soc. Am. J. 1985, 49 (3), 645–651. Plante, A.F. Soil aggregate turnover and the physical protection of soil organic matter as measured using dy-labelled tracer spheres. Ph.D. thesis, University of Alberta, Edmonton, Canada, AB, 2001.
Oxygen Diffusion Rate and Plant Growth Witold Ste¸ pniewski Technical University of Lublin and Polish Academy of Sciences, Lublin, Poland
INTRODUCTION
SOIL PARAMETERS AND ODR
What Is Oxygen Diffusion Rate?
The ODR index reflects comprehensively the soiloxygen availability, as it comprises the effect of all the factors such as respiration, moisture, and the physical particle arrangement that influence the concentration of oxygen in soil air, the effective thickness of the water films around the roots, and their diffusion characteristics. The ODR values in soils vary, most frequently, within a range from 0 to 200 mg m2 sec1 (Figs. 1–3). They decrease with soil-moisture content and with soil compaction and they increase with moisture tension, with air-filled porosity of the soil, and with oxygen content in soil air.[4] Due to this, a decrease in ODR is expected usually with depth, especially just above the ground water table. An example of the relationship of ODR on soil-moisture tension and bulk density is presented in Fig. 1. Beyond the soil moisture content and bulk density, the value of ODR is related to many other soil parameters. The dependence on the gas diffusion coefficient[6] is shown in Fig. 2. The relationship with air permeability of the soil[6] is illustrated in Fig. 3. The value of ODR is related also to redox potential[4] and to dehydrogenase activity.[7]
Oxygen diffusion rate (ODR) is an electrochemical method of assessment of soil oxygen availability to plant roots. It is based on the analogy of oxygen uptake by plant roots and by platinum wire electrode placed in the soil. Oxygen diffusion rate is of importance because availability of oxygen to plant roots is a basic factor of soil productivity. A knowledge of the method of measurement of ODR helps one to evaluate oxygen requirements of particular plant species at different stages of their development. Moreover, we can use it as a diagnostic tool to assess the oxygen availability in a particular soil under definite conditions. Concept and Principle of the Method As early as 1926, Hutchins[1] expressed a conviction that it is not so much the concentration of oxygen in the soil as the possibility of its uptake by plant roots that determines the plant response to the oxygen conditions in the soil. This idea was realised in 1952 by Lemon and Erickson,[2] who designed an electrode simulating oxygen uptake by plant roots. An important role in this concept is played by the presence of water or exudate films on the root surface. These films, due to the low diffusion coefficient of gases in water, form a significant obstacle in the path of oxygen from the soil air to the root.[2,3] The principle of this method consists in the measurement of the amount of oxygen diffusing onto the surface of a platinum wire electrode (usually 0.5–1.0 mm in diameter and several mm in length), where it is reduced electrochemically to hydroxide ions or water.[2,3] In practice, the value of ODR is determined on the basis of measurement of the diffusion current intensity on a platinum electrode, which is negatively polarized in order to provide specific conditions for the reduction of oxygen molecules only. The platinum wire is therefore a model of oxygen absorbing root, and the intensity of oxygen flux to the electrode indicates the maximum amount of oxygen that would be available for a plant root placed in the same spot as the electrode. 1236 Copyright © 2006 by Taylor & Francis
ODR AND PLANT RESPONSE Seedling Emergence In a typical relationship between plant emergence and ODR[4] starting with the highest values of ODR, initially we observe a plateau range with insignificant differentiation in emergence. Then, after reaching a certain limiting value a significant decrease in the final emergence percentage in comparison with the germination capacity is observed. Thereafter, there is a rapid linear decline in the number of emerging plants as the ODR decreases; this number falling to zero at the critical ODR. It was found that the limiting values for the plant emergence range from 25 to 100 mg m2 sec1 and the critical values from 7 to 40 mg m2sec1.[4] Root Response Root tissue is that part of a plant which is subjected first to oxygen deficiency or anoxia, and the Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120006603 Copyright # 2006 by Taylor & Francis. All rights reserved.
Oxygen Diffusion Rate and Plant Growth
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Fig. 3 Oxygen diffusion rate vs. air permeability (k) of the soil. Collective data for 24 soil horizons of six different soil profiles from Hungary. (Adapted from Ref.[6].) Fig. 1 Oxygen diffusion rate vs. bulk density and soil moisture tension in a loamy textured chernozem rendzina soil. (Adapted from Ref.[5].)
consequence is a decrease of the root biomass at low ODR.[4,8] It was confirmed that wheat-root population in soil[9] increased linearly with ODR in the interval from 40 to 60 mg m2 sec1 more than 5 fold. Rootelongation rate of three desert shrubs also increased with ODR in the interval 30–90 mg m2 sec1.[10] It was found that for numerous grass species critical ODR value is below 10 mg m2 sec1.[4] In case of lowland rice, root porosity decreased from 23% at
Fig. 2 Oxygen diffusion rate vs. relative gas diffusion coefficient D/D0 in soil, where gas diffusion coefficient D of a gas relates to the soil and D0 to the atmospheric air at the same temperature and pressure conditions. Collective data for 24 soil horizons of six different soil profiles from Hungary. (Adapted from Ref.[6].)
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ODR 100 mg m2sec1.[4] Shoot Response Shoot response to root hypoxia expressed by the ODR values has been studied intensively. As it was found, the uptake of water by orange seedling was 2–3 times higher at ODR >60 mg m2 sec1 as compared to that at ODR 5000 m in altitude) emerging from these chains; and 2) nonvolcanic rocks or hard lava flows with notched summits and steep slopes.[4]
SOILS Pa´ramos soils have been described by Jenny since 1948.[6] Soils evolve in function of the convergent effects of low temperature, high soil moisture, and Al availability.[7] In the supra-Pa´ramo, organic matter production decreases with altitude, and soils are very shallow, with umbric epipedon[8] and periglaciar features. In nonvolcanic Venezuelan areas, Cryepts are dominant. The presence of giant rosette plants gives the soil pattern discontinuous properties with higher carbon content only at soil surface and around the rosette.[9] In volcanic areas, during glacier periods, ice caps protected soils from ash deposits. The most recent deposits are weakly weathered and form Vitrandic Cryents. At lower altitudes, in humid conditions, the availability of Al is the second important factor in soil formation. When Al availability is very low, Humods and Fragiaquods are observed on gneiss and micaschists rich in quartz (Podocarpus Paramo in the south of Ecuador). With higher Al availability, Inceptisols (Dystrudept) form with an umbric epipedon. With
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high Al availability, Al forms very stable complexes with organic matter.[10] The main pedological process is an acidic complexolitic andosolization with Al þ 1=2 Fe oxalate extract >2% and Al% pyropyrophosphate=Al% oxalate >0.5 characteristic of nonallophanic Andisols,[11] which are the more extended soil types in the Pa´ramos. On recent volcanic ashes, important Al availability leads to a very fast soil formation, with Vitrands forming in less than 1000 years. The farther the deposits are from their emission source, the finer are the ashes, and the faster is the rate of weathering. The older, most evolved soil profiles ( 3000 years) have the lowest base reserve and can been classified as Udands. The nonallophanic andosolization process could also be active on nonvolcanic Al-rich substrates (paleo-oxisols or metamorphic rocks). All of these soils are acidic and have anionic retention capacities (especially for P and S). Pa´ramo Soils and Carbon Content All Pa´ramo soils are very rich in organic carbon. In the Paramo of Northern Peru, soils contain over 10 kg m2 C, whatever the nature of the parent rock (limestones, volcanic rocks, or sandstones).[12] Low temperatures and stable organo-metallic complexes[7] reduce the biological activity and therefore decrease the rate of organic matter mineralization. High carbon accumulation results from different pedologic processes on successive ash layers, but also on colluvial buried soils on steep slopes. Carbon sequestration can exceed 85 kg m2 in the polygenic nonallophanic matured Andisols of Northern Ecuador (Table 2, Photo 1).[13] Altitude increases the soil organic carbon content with a maximum density (reaching 10 g cm3) at around 3900 m. These Andisols have black thick melanic epipedon attributed to the presence of humic acids produced by the degradation of Poaceae family plants,[11] and can been classified as Melanudands (Photo 1).[8] Pa´ramos and Water Cycle Regulation The water content in nonallophanic Andisols at 1500 kPa is over 1000 g kg1 (Hydric properties).[8] Table 2 Carbon Pool (kg m2) of some Pa´ramos soils Place
Pichincha Carchi Cajas Fierro Cerro Sabanilla (1) (2) (3) Urcu (4) Toledo (5) (6)
A
35.6
46.3
B
56.7
86.4
36.4
34.1
15.8
11.2
1: Thaptic Hapludand; 2: Hydric pachic Melanudand; 3: Hydric Melanudand; 4: Humic Andic Hapludox; 5: Humic Dystrudept; 6: Typic Fragiaquod. A: First meter of the profile; B: whole profile.
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and can be 2000 g kg1 at field capacity. The formation of an organo-metallic complex network leads to important microporosity. The more mature the soils, the richer they are in humic substances, and the higher is their microporosity. For matured Andisols, micropores with a radius 2=3
c=b < 2=3
Class II
Spheroid
b=a > 2=3
c=b > 2=3
Class III
Blade
b=a < 2=3
c=b < 2=3
Class IV
Rod
b=a < 2=3
c=b > 2=3
a, b, c are the crystallographic axes. (Adapted from Ref.[7].)
Table 2 Roundness grades Class limits Grade term
Ref.
[9]
Very angular
[10]
Ref.
Ref.[11] Rho scalea
0.12–0.17
0.00–1.00
0–0.15
0.17–0.25
1.00–2.00
Subangular
0.15–0.25
0.25–0.35
2.00–3.00
Subrounded
0.25–0.40
0.35–0.49
3.00–4.00
Rounded
0.40–0.60
0.49–0.70
4.00–5.00
Well-rounded
0.60–1.00
0.70–1.00
5.00–6.00
Angular
a
Based on Ref.[10] class limits. (Adapted from Ref.[3].)
These processes are common in diagenesis and weathering processes associated with sedimentary rocks and sedimentary bodies (alluvium and colluvium), and are integral in the rock cycle of igneous, sedimentary, and metamorphic rocks. In soils, shape analysis is used to determine uniformity of parent material and origin and mode of soil formation, and used in mineral and structure analysis. Soil-forming processes at or near the earth’s surface can then be inferred to link parent material origin and genesis of soil materials and soil profiles.
CONCLUSIONS Particle shape classes and secondary clay mineral content have been used in combination to determine soil
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texture grades. Texture grades and their arrangement in soil structure largely determine pore volume in soils, which can be related to water and air-filled porosity as well as soil strength which has implications for soil– plant root relationships. Most of the use of particle shape analysis has been confined to soil genesis studies. These studies together with secondary clay mineral formation include interpretations of initial parent materials, inferred factors, and processes used to describe the nature and genesis of soil particulate mineralogical properties and hence, the distribution of contiguous soils in a landscape.
REFERENCES 1. American geological institute. Dictionary of Geological Terms, 2nd Ed.; Dolphin Reference Books: U.S.A., 1962. 2. Pettijohn, F.J.; Potter, P.E.; Siever, R. Sand and Sandstone; Springer: New York, 1987. 3. Brewer, R. Fabric and Mineral Analysis of Soils; Wiley: U.S.A., 1964. 4. Wadell, H. Volume, shape, and roundness of rock particles. J. Geol. 1932, 40, 443–451. 5. Wadell, H. Sphericity and roundness of rock particles. J. Geol. 1933, 41, 310–331. 6. Wadell, H. Volume, shape and roundness of quartz particles. J. Geol. 1935, 43, 250–279. 7. Zingg, Th. Beitragzur Schotteranalyse. Schweiz. Mineral. Petrog. Mitt. 1935, 15, 39–140. 8. Krumbein, W.C. Measurement and geological significance of shape and roundness of sedimentary particles. J. Sediment. Petrol. 1941, 11, 64–72. 9. Pettijohn, F.H. Sedimentary Rocks, 2nd Ed.; Harper Brothers: New York, 1957. 10. Powers, M. A New roundness scale for sedimentary particles. J. Sediment. Petrol 1953, 23, 117–119. 11. Folk, R.L. Student operated error in determination of roundness, sphericity and grain size. J. Sediment. Petrol. 1955, 25, 297–301.
Pedogenic Silica Accumulation Katherine J. Kendrick United States Geological Survey, Pasadena, California, U.S.A.
INTRODUCTION Pedogenic silica is defined as silica that has precipitated in the soil environment, taking the form of opal-A, opal-CT, or microcrystalline quartz. Opaline silica, which is amorphous to poorly crystalline, is the most common form of pedogenic silica.[1,2] Pedogenic silica is formed in arid, semiarid, and Mediterranean climates where there is adequate precipitation to mobilize the silica, but not so much as to leach the silica out of the profile. Pedogenic silica accumulation has been reported throughout the western U.S., Australia, Italy, South Africa, and New Zealand.[3] In its most advanced form, it cements the soil fabric to form extremely hard horizons known as duripans or silcrete.
SOURCES OF PEDOGENIC SILICA Pedogenic silica is derived from two main sources. The weathering and hydrolysis of primary silicate minerals provide for the slow release of silica into solution as silicic acid. Easily weathered silicates, such as olivine and Ca-plagioclase, are particularly likely to contribute silica into solution. The second source is from the weathering of primary amorphous silica, including volcanic glass and biogenic silica (e.g., phytoliths, diatoms). Such amorphous silica is the most soluble form of silica found in the soil environment. Weathering of glassy volcanic products, including ash and tephra, to release silicic acid into solution occurs readily in soils.
DISSOLUTION OF SILICA Factors controlling the dissolution of silica include soil solution pH, the presence of organic matter, the particle size of the material, and the presence of coatings on grains. The solubility of silica is moderate throughout the pH range of most soils, but is particularly high at pH values 9, as found in sodium carbonate soil systems. Organic matter enhances the dissolution of silica, including quartz, and impedes precipitation.[3] The dissolution of quartz has been shown to be highest in the root zone due to organic complexation of monosilicic acid.[4] On the other hand, organic matter may actually form a coating on opal, impeding its dissolution.[5] Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120001755 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
Because of surface area effects, smaller particles are more susceptible to dissolution. This phenomenon accounts for the fact that quartz does not persist in the clay fraction of most soils.[6] Aluminum- and Fe-oxyhydroxides can form insoluble coatings on grains, thereby decreasing rates of dissolution from those grains.[3]
MOVEMENT AND PRECIPITATION OF SILICA Silica is moved in solution through the soil as silicic acid. Incomplete leaching allows for the precipitation of this silicic acid in the pedogenic zone. During drying induced by evapotranspiration, SiO4 is adsorbed onto surfaces, forming amorphous opaline silica. This process led to the silica cementation of south-facing terrace edges on the central California coast.[7] Alternatively, in situ alteration of eolian dust to opal-A, rather than precipitation from silica in soil solution, has been proposed for duripans in Idaho.[8] The eolian dust comprised volcanic glass and feldspars. Conditions favoring the precipitation of silica from solution include pH values less than 7, a high available surface area within the soil fabric, and high ionic strength of the soil solution. Although a high available surface area favors precipitation, silica cementation is most common in medium-textured parent materials with abundant skeletal grains. The grain-to-grain cementation is an important component in the formation of a duripan.[6] Aluminum- and Fe-oxyhydroxides specifically adsorb soluble silica. Since these compounds are nearly ubiquitous in soils, often as coatings on other grains, they form a significant sink for the precipitation of silica on surfaces.[3]
SILICA MORPHOLOGY Stages of silica cementation have been defined for coarse grained deposits in arid climatic regimes.[9] The first stage is precipitation of silica on the undersides of clasts. These are termed pendants, and are equivalent to opal beards in Australian soil descriptions.[10] Dramatic examples of opal pendants have been described in some central Californian soils.[11] The second stage is precipitation within the matrix, 1251
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where silica forms bridging contacts between grains. The third stage is silica precipitation on all sides of the clasts, and the final stage is a laminar cap above a plugged matrix. Apart from silica precipitation on gravels, silica can cement the finer matrix materials into nodules termed durinodes. Duripans are defined as soil horizons that are irreversibly cemented by various forms of silica such that they do not slake after soaking in water or hydrochloric acid.[12] Duripans take two general forms. In Mediterranean climates, duripans often have prismatic structure and pedogenic calcite is minimal or absent.[1] Small opal flocs within the matrix of the prisms are the
Pedogenic Silica Accumulation
precursors to durinodes. Further development of the duripan yields extensive grain-to-grain cementation in the soil matrix (Fig. 1) and silica coatings on the tops and upper sides of the prisms. Ultimately, silica laminae with platy structure cap the prismatic horizon.[1] This is in contrast to duripans that form in arid environments, which typically have a large component of pedogenic calcite and are characterized by a platy structure throughout, with plates 1–15 cm thick.[13] As little as 10% Si as opaline silica is adequate to cement horizons effectively, and form a fully developed duripan.[1] Thorough cementation of a soil horizon to form a duripan requires geomorphic stability of long duration, particularly in the absence of readily soluble volcanic ash. The ancient landscapes of Australia fit this criterion. Silica cemented horizons in Australia are common and are referred to as silcrete, duricrust, and grey billy.[10] Silica cementation has also been reported in hardsetting soils. Hardsetting soils have one or more horizons with hard to very hard consistence when dry. This phenomenon is recognized in soils with alternating seasons of wetting and drying, primarily those in Australia. Hardsetting soils eventually slake on wetting, and are thus not irreversibly cemented.[14] Amorphous particles and coatings of silica have been documented in these soils,[14] suggesting that silica is an important constituent in the process of seasonal cementation.[15] The easily mobilized silica might be ephemeral, and may or may not be related to incipient formation of a duripan.
REFERENCES
Fig. 1 Scanning electron micrograph of soil fabric in a duripan from southern California. (A) Primary mineral grains (P: plagioclase; B: biotite; Q:, quartz) cemented by opaline silica (O: opaline silica). (B) Close-up view of the lower left portion of Fig. 1A, showing biotite grains embedded in opaline silica. (Photo by Dr Krassimir Bozhilov, Central Facility for Advanced Microscopy and Microanalysis, UC Riverside.)
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1. Flach, K.W.; Nettleton, W.D.; Gile, L.H.; Cady, J.G. Pedocementation: induration by silica, carbonates, and sesquioxides in the quaternary. Soil Sci. 1969, 107, 442–453. 2. Chadwick, O.A.; Hendricks, D.M.; Nettleton, W.D. Silica in duric soils: 1. A depositional model. Soil Sci. Soc. Am. J. 1987, 51, 975–982. 3. Dress, L.R.; Wilding, L.P.; Smeck, N.E.; Senkayi, A.L. Silica to soils: quartz and discordered silica polymosphs. In Minerals in Soil Environments, 2nd Ed.; Dixon, J.B., Weed, S.B., Eds.; Soil Sci. Soc.: Am. Madison, WI, 1989; 913–974. 4. Cleary, W.J.; Conolly, J.R. Embayed quartz grains in soils and their significance. J. Sediment. Petrol. 1972, 42, 899–904. 5. Wilding, L.P.; Drees, L.R. Contributions of forest opal and associated crystalline phases to fine silt and clay fractions of soils. Clays Clay Min. 1974, 22, 295–306. 6. Moody, L.E.; Graham, R.C. Silica-cemented terrace edges, central California coast. Soil Sci. Soc. Am. J. 1997, 61, 1723–1729.
Pedogenic Silica Accumulation
7. Blank, R.R.; Fosberg, M.A. Duripans in Idaho, U.S.A. in situ alteration of eolian dust (loess) to an Opal-A=XRay amorphous phase. Geoderma 1991, 48, 131–149. 8. Norton, L.D. Micromorphology of silica cementation in soils. In Soil Micromorphology: Studies in Management and Genesis; A.J. Ringrose-Voase and G.S. Humphreys, Eds.; Proc. IX Int. Working Meeting on Soil Micromorphology, Townsville, Australia, July 1992; Dev. Soil Sci., 1994; Vol. 22, 811–824. 9. Harden, J.W.; Taylor, E.M.; Reheis, M.C.; McFadden, L.D. Calcic, gypsic and siliceous soil chronosequences in arid and semiarid environments. In Occurrence, Characteristics, and Genesis of Carbonate, Gypsum, and Silica Accumulations in Soils; Nettleton, W.D., Ed.; Soil Sci. Soc. of Am. Spec. Publ.: Madison, WI, 1991; Vol. 26, 1–16. 10. Milnes, A.R.; Wright, M.J.; Thiry, M. Silica accumulations in saprolites and soils in South Australia. In Occurrence, Characteristics, and Genesis of Carbonate,
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11.
12. 13.
14.
15.
Gypsum, and Silica Accumulations in Soils; Nettleton, W.D., Ed.; Soil Sci. Soc. of Am. Spec. Publ.: Madison, WI, 1991; Vol. 26, 121–149. Munk, L.P.; Southard, R.J. Pedogenic implications of opaline pendants in some California late-pleistocene palexeralfs. Soil Sci. Soc. Am. J. 1993, 57, 149–154. Soil Survey Staff. In Soil Taxonomy; U.S. Gov. Printing Office: Washington, DC, 1975. Chadwick, O.A.; Graham, R.C. Pedogenic processes. In Handbook Soil Science; Summer, M.E., Ed.; CRC Press: Boca Raton, FL, 2000; E-41–E-75. Chartres, C.J.; Norton, L.D. Micromorphological and chemical properties of Australian soils with hardsetting and duric horizons. Dev. Soil Sci. 1994, 22, 825–834. Chartres, C.J.; Kirby, J.M.; Raupach, M. Poorly ordered silica and aluminasilicates as temporary cementing agents in hard-setting soils. Soil Sci. Soc. Am. J. 1990, 54, 1060–1067.
Pedological Modeling Ronald G. Amundson University of California, Berkeley, California, U.S.A.
INTRODUCTION ‘‘The fascinating impressiveness of rigorous mathematical analysis, with its atmosphere of precision and elegance, should not blind us to the defects of the premise that condition the whole process’’ by T. C. Chamberlin,[1] commenting on Lord Kelvin’s (ultimately incorrect) calculation of the age of the Earth.
In pedology, and in other sciences, ‘‘models’’ are increasingly used as tools for understanding natural phenomena. But what is a model, how are models used in pedology, and how are models developed and modified?
OVERVIEW To begin, the term ‘‘model’’ has been used interchangeably in pedology with other concepts, sometimes leading to confusion or miscommunication. Very simply, a ‘‘model’’ has been described by some as ‘‘a form of highly complex scientific hypothesis,’’[2] that is ‘‘a simplified and idealized description or conception of a particular system, situation, or process (often in mathematical terms) that is put forward as a basis for calculations, predictions, or further investigation.’’[3] As briefly outlined below, the mathematical approaches to describe a phenomenon can be varied, but all must rest on a solid understanding of the soil, and the factors and processes, which affect it. This empirical knowledge in turn constrains the ‘‘assumptions,’’ which underlie any mathematical model development. A model based on an incorrect, or poorly developed, understanding of a soil and the processes that affect it will likely be unable to describe the processes of interest, but that inability may in turn inspire the modeler to better understand the soil. Therefore, modeling can help refocus attention to fieldwork and to the type of data to be collected. A specific example of how assumptions affect the development of a model is given later in this entry. The first step in modeling soils—or anything—is to define the object of interest. In applying models to pedology, it should be recognized that soil is, in reality, a continuum of objects distributed across the earth’s surface—both in space and time. The exact lateral 1254 Copyright © 2006 by Taylor & Francis
boundary between one ‘‘soil’’ and another, or the vertical boundary between soil and nonsoil, is arguably impossible to determine. Jenny[4] first applied principles derived from the physical sciences to the conceptualization and modeling of soils. Jenny’s approach was to divide the continuum of soils on the earth’s surface into ‘‘systems,’’ which are arbitrarily defined, discrete, three-dimensional segments of the landscape that are amenable to mass or energy budgeting. The volume of these systems (both the chosen area and depth) is arbitrary, but it sets the stage for the mathematical formulations that are chosen to represent or describe it. A second important aspect of soils is the vast amount of time, and the array of unknown processes, that may have affected any soil system. This complex history in turn forces pedologists to develop tools, concepts, and modes of enquiry not always confronted by their experimental colleagues. Finally, soil formation is the result of an incompletely understood array of processes, and pedological models invariably are attempts to mathematically capture one, or at the most, a very restricted subset of the full suite of biogeochemical processes that affect a soil system. In the pedological literature, more attention has possibly been devoted to classifying and discussing models[5] than actually developing them. Unfortunately, much discussion has focused on the ‘‘pros and cons’’ of the Factors of Soil Formation. A System of Quantitative Pedology[4] in the realm of pedological models. Briefly, the factorial ‘‘model’’ discussed in a book-length treatise by Jenny[4] can be symbolically represented as s ¼ fðcl; o; r; p; t; . . .Þ where s is the soil properties; cl, climate; o, biota; r, topography; p, parent material; and t, time.[4,6] The general truthfulness of this statement is almost beyond dispute (virtually every pedologist would ultimately have to agree that soil forms in response to variations in these factors, and that soil properties can also be numerically correlated with variations in these factors). Indeed, soil is ‘‘defined’’ in terms of this statement: Soil is the ‘‘collection of natural bodies occupying portions of the earth’s surface that support plants and that have properties due to the integrated effect Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042725 Copyright # 2006 by Taylor & Francis. All rights reserved.
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of climate and living matter, acting upon parent material, as conditioned by relief, over periods of time.’’[7]
Based on this definition, it would be more correct to define the state factor ‘‘model,’’ or ‘‘theory’’ as it has been alternately called, as a pedological ‘‘law’’ given its universal truthfulness and common definitions of scientific laws.[8] At the very least, it is a fundamental underlying theory of pedology in the sense of Kuhn.[9] This definition would also allow the discussion of models in pedology to move beyond this fundamental truism (and a useful quantitative and mathematical tool in its own right) to the development of mathematical models as they are commonly considered and used in geochemistry, geophysics, and related fields. The remainder of this entry deals with these more practical modeling issues.
extended for use in stable isotopic studies of soil organic matter[11] and in modeling turnover times of soil organic carbon.[12] However, the analytical model, as developed by Jenny, assumes constant inputs with time (a restriction that he noted does not occur in all situations) and constant decomposition rates with time. It also assumes that all organic matter is homogeneous (and by implication, has the same decomposition rates). Work over the past 15 years in particular has revealed that soil organic matter (and even litter layers) can best be viewed as multiple pools of soil organic matter, each with their own characteristic input and decomposition rates. In simplest terms, multiple pool models of soil organic matter can be expressed as n X dC ¼ ðIi ki Ci Þ dt i¼1
ð3Þ
MODELING PROCESSES Typical approaches to mathematically modeling soil processes involve the development of a mass or energy balance model. The mathematics used will ultimately hinge upon one’s understanding of the soil properties, the processes that presumably control them, and how these processes may vary over time. Some of the simplest models may be analytical models with time independent variables. Alternative modeling approaches may involve the abandonment of time invariant parameters and ultimately, the incorporation of relatively random changes in the rate of the process and factors that affect it. As an example, I begin with possibly the first true mathematical model of a pedogenic process—a time dependent, analytical, mass-balance model of O horizon formation in forest soils developed by Jenny, Gessel, and Bingham.[10] Jenny, Gessel, and Bingham[10] defined the system of study, discussed the processes that affect it, and, for the simplest cases they considered (tropical forests with nearly constant litter inputs with time), described the change in O horizon mass (F, in mass per area) with time dF ¼ Adt kðF þ AÞdt
ð1Þ
where A is litter inputs (mass=area=time), and k, decomposition constant (1=time) (Ref. [10] gives a fuller discussion of calculation and definition of k). Upon integration, the solution to Eq. (1) provided by Jenny was F ¼
Að1 kÞ ð1 ekt Þ k
ð2Þ
This model, and permutations of it, has served as the foundation for decades of research and modeling of the soil organic C budget. Today the model has been
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where C is the total mass of soil C (mass=volume); I, inputs of pool i (mass=volume=time); ki, decomposition constant of pool i (1=time); and Ci, mass of soil C in pool i (mass=volume).[11] Even these multiple pool models do not capture other aspects of soil formation, the variation in soil C with depth, and the likelihood that the process may have varied unpredictably over time. To address the first issue, models may include a downward transport term and depth dependent inputs. For a single pool of organic matter, a basic depth dependent model is dC=dt ¼ I u
@C kC @Z
ð4Þ
where u is the advection coefficient (distance=time).[11] Even these models can be made more complex, for example to include the process of diffusion.[13] Analytical solutions to all the aforementioned models require time invariant parameters. The inclusion of time-dependent parameters may be accomplished through numerical means. Yet, soils form over thousands to millions of years, with numerous unknown perturbations to the system that elude the fundamental framework of these simple models.[14] It is these real world complications imposed by nature that weaken the utility of relatively simple, time invariant, deterministic models. Recently, Phillips[14] began the discussion of applying nonlinear dynamical system theory to soil modeling, with the goal of explicitly incorporating the role that random differences in initial conditions and historical contingencies have on the processes of soil formation. Undoubtedly, work of this nature is one of the future challenges in the field of pedological modeling.
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CONCLUSIONS While models are powerful means of testing hypotheses and synthesizing contemporary knowledge in a concise way, the previous discussion serves to illustrate that models of all types are simplified, incomplete, mathematical descriptions of the ‘‘real’’ world. Increasingly, it is emphasized that models can never be fully verified (confirmed as the establishment of truth).[2] Experience shows that multiple models (or versions of the same model) may faithfully mimic empirical observations of interest, a dilemma illustrating a practical verification problem. In addition, mathematical models may be internally correct but they may poorly represent the phenomena they intend to describe because of incomplete knowledge of the system and, as a result, incorrect assumptions. Knowledge of the soil is essential in modeling, for as Baker[15] has recently noted, ‘‘mathematics (is) the science that draws necessary conclusions without regard to facts.’’ Given the ultimate simplicity and abstractness of models, and the ultimate complexity of nature in general, and soils in particular, the question ‘‘why model in the first place?’’ may be asked.[2] Pedological processes are first order controls on global atmospheric[16] and aquatic chemistry, and even relatively simple analytical models of soil processes have thus far proven useful to link these global reservoirs. The truly unique role for pedologists, in addition to applying mathematics on their own, is to provide the unique conceptual foundation peculiar to soils—one informed by extensive field observations guided by ideas generated during previous modeling attempts—that will make pedological models relevant to scientists and society.
REFERENCES 1. Chamberlin, T.C. On Lord Kelvin’s Address on the Age of the Earth as an Abode Fitted for Life; Smithsonian Institution Annual Report: Washington, DC, 1899; 223–246.
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Pedological Modeling
2. Oreskes, N.; Shrader-Frechette, K.; Belitz, K. Verification, validation, and confirmation of numerical models in the earth sciences. Science 1994, 263, 641–646. 3. The Oxford English Dictionary, 2nd Ed.; Clarendon Press: Oxford, 1989. 4. Jenny, H. Factors of Soil Formation. A System of Quantitative Pedology; McGraw Hill Book Co.: New York, 1941; 281 pp. 5. Hoosbeek, M.R.; Amundson, R.; Bryant, R.B. Pedological modeling. In Handbook of Soil Science; Sumner, M.E., Ed.; CRC Press: Boca Raton, FL, 1999; E77–E116. 6. Amundson, R.; Jenny, H. On a state factor model of ecosystems. Bioscience 1997, 47, 536–543. 7. Soil survey staff. Soil Survey Manual; U.S. Dep. Agric. Handbook No. 18; U.S. Govt. Printing Office: Washington, DC, 1951; 503 pp. 8. Morris, C., Ed. Academic Press Dictionary of Science and Technology; Academic Press: New York, 1992. 9. Kuhn, T.S. The Structure of Scientific Revolutions, 2nd Ed.; University of Chicago Press: Chicago, 1970; 210 pp. 10. Jenny, H.; Gessel, S.P.; Bingham, F.T. Comparative decomposition rates of organic matter in temperate and tropical regions. Soil Sci. 1949, 68, 419–432. 11. Amundson, R.; Baisden, W.T. Stable isotope tracers and models in soil organic matter studies. In Methods in Ecosystem Science; Sala, O., Mooney, H., Howarth, B., Jackson, R.B., Eds.; Springer Verlag: New York, 2000; 117–137. 12. Trumbore, S.E. Comparison of soil carbon dynamics in tropical and temperate soil using radiocarbon measurements. Global Biogeochem. Cycles 1993, 9, 515–528. 13. Elzein, A.; Balesdent, J. Mechanistic simulation of vertical distribution of carbon concentrations and residence times in soils. Soil Sci. Soc. Am. J. 1995, 59, 1328–1335. 14. Phillips, J.D. On the relations between complex systems and the factorial model of soil formation (with discussion). Geoderma 1998, 86, 1–42. 15. Baker, V.R. Geosemiosis. Geol. Soc. Am. Bul. 1999, 111, 633–645. 16. Amundson, R.; Stern, L.; Baisden, T.; Wang, Y. The isotopic composition of soil and soil-respired CO2. Geoderma 1998, 82, 83–114.
Pedotransfer Functions J. H. M. Wo¨sten Alterra Green World Research, Wageningen, The Netherlands
INTRODUCTION Simulation models, which are indispensable tools in modeling water and solute movement into and through soil, require as key input parameters easily accessible and representative hydraulic characteristics. Techniques to measure these characteristics are relatively time-consuming and therefore costly. At the same time, good predictions of the characteristics instead of direct measurements may be accurate enough for many applications. Considering the desired accuracy and the available financial resources, it is rewarding to analyze existing databases containing measured hydraulic characteristics and to establish relationships that predict the characteristics from measured basic soil data. These predictive relationships are called ‘‘pedotransfer functions’’ (PTFs)[1] and they essentially translate data ‘‘we have’’ into data ‘‘we need.’’ Basically, PTFs relate soil characteristics being assembled during soil survey to more complex characteristics needed for simulation. Predicting soil hydraulic characteristics dominates the research field, though soil chemical and soil biological characteristics are also being predicted. Several reviews on PTF development and use have been published.[2,3] Large databases on measured hydraulic characteristics, such as UNSODA,[4] HYPRES,[5] WISE,[6] and United States Department of Agriculture Natural Resource Conservation Service pedon database,[7] form the essential, basic sources of information for the derivation of PTFs. In using PTFs, insight is needed to determine the input variables that are to be included in a PTF, what technique is to be used to establish a PTF, and how accuracy and reliability of PTFs are to be quantified.
FUNCTIONS USED TO DESCRIBE THE WATER RETENTION AND HYDRAULIC CONDUCTIVITY CHARACTERISTICS Describing hydraulic characteristics as functions rather than as tables has the clear advantage that they can be easily incorporated in simulation models. There exists a wide range of different equations for the description of the characteristics. The following equations to describe volumetric soil water content, y, and hydraulic Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042726 Copyright # 2006 by Taylor & Francis. All rights reserved. Copyright © 2006 by Taylor & Francis
conductivity, K, as functions of pressure head, h, are widely used[8] yðhÞ ¼ yr þ
KðhÞ ¼ Ks
ys yr ðl þ jahjn Þ11=n
½ðl þ jahjn Þ11=n jahjn1 2 ðl þ jahjn Þð11=nÞðlþ2Þ
ð1Þ
ð2Þ
In these equations, the subscripts r and s refer to residual and saturated values and y, n, and l are parameters that determine the shape of the curve. The residual water content yr refers to the water content, where the gradient dy=dh becomes zero (h ! 1). The parameter a (1=cm) approximately equals the inverse of the pressure head at the inflection point. The dimensionless parameter n reflects the steepness of the curve. The dimensionless parameter l determines the slope of the hydraulic conductivity curve in the range of more negative values of h. Pedotransfer functions to predict the model parameters yr, ys, Ks, a, l, and n from basic soil data were built by many authors.[9] Fig. 1 shows the mean water retention and hydraulic conductivity characteristics, also called class PTFs, for the texture class ‘‘medium fine topsoil.’’[5] SELECTION OF PEDOTRANSFER FUNCTION PREDICTOR VARIABLES Soil properties affecting water retention and hydraulic conductivity are manifold.[10] Table 1 lists the properties used most often as predictors because of their availability and because they proved to be the most promising ones. ‘‘Particle size distribution’’ is used in almost all PTFs. Particle size classes differ in different national and international classification systems, and so the number and the size of classes used in PTFs may also differ. Using sand, silt, and clay contents is a common approach. ‘‘Limited, measured water retention data’’ at, for instance, two pressure heads may dramatically improve predictions of the complete water retention characteristic. ‘‘Porosity or bulk density’’ is an important variable in many PTFs. 1257
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Pedotransfer Functions
Fig. 1 Geometric mean water retention (A) and hydraulic conductivity (B) characteristic solid lines, standard deviations bars, and van Genuchten fits dotted lines for the texture class ‘‘medium fine topsoil.’’
‘‘Soil structure and morphology descriptors’’ such as the parameter topsoil and subsoil are successfully included in PTFs. ‘‘Landscape position’’ is used as a topographic variable in PTFs. ‘‘Organic matter content’’ is often used as predictor, but because bulk density and organic matter content are correlated, bulk density may effectively substitute organic matter content. ‘‘Mechanical properties and shrink–swell parameters,’’ as characterized by the coefficient of linear
extensibility (COLE), are used to estimate both water retention and Ks.
METHODS TO DEVELOP PEDOTRANSFER FUNCTIONS When the set of PTF input parameters is defined and the PTF output is decided upon, a method is selected to relate input and output. The most prominent methods to create this relationship are discussed below.
Table 1 Soil properties often used in PTFs Particle size properties Sand, silt, clay
Hydraulic characteristics
Chemical/mineralogical properties
Bulk density
Organic carbon
33 kPa
Porosity
Organic matter
1500 kPa
Horizon
CEC
Structure
Clay type
Median or geometric mean particle size
Grade Size Shape
CaCO3 Iron
Water-stable aggregates
Color Consistence Pedality Landscape position
Fine sand Very coarse sand, coarse fragments
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Water content at
Morphological properties
Reference moisture retention curve
Mechanical properties Penetration resistance
Pedotransfer Functions
Table 2 Continuous PTFs developed from the HYPRES database ys ¼ 0.7919 þ 0.001691C 0.29619D 0.000001491S2a þ 0.0000821OM2 þ 0.02427C1 þ 0.01113=S þ 0.01472ln(S) 0.0000733OMC 0.000619DC 0.001183DOM 0.0001664 topsoil S (R2 ¼ 76%) a ys is the saturated water content in the van Genuchten equations; C, percentage clay (i.e., percentage 8.7. A very high pH indicates the presence of magnesium carbonate.[9] Encyclopedia of Soil Science DOI: 10.1081/E-ESS-120042727 Copyright # 2006 by Taylor & Francis. All rights reserved.
Petrocalcic Horizons, Soils with
Fig. 1 Below an A horizon (1) is a layered noncompact petrocalcic horizon (crust) (2), over an unlayered (nonplaty) petrocalcic horizon (3), on a calcic horizon (4).
Soils with petrocalcic horizons in environments with restricted drainage tend to form montmorillonite, attapulgite, and sepiolite clay minerals.[6–8,10]
VERTICAL SUCCESSION OF THE CALCIC AND PETROCALCIC HORIZONS Below A or B horizons, the accumulation of calcium carbonate can be of three types: Slightly differentiated: the distribution of carbonates is diffuse, sometimes with pseudomycelia with very diffuse upper and lower limits. Moderately differentiated: the carbonates in the calcic horizon occur partly as diffuse distributions in the soil matrix and partly as concentrations, forming cutans, soft and hard nodules, or veins, with diffuse upper and lower limits. Highly differentiated (petrocalcic): the carbonates form laterally continuous concentrations
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Fig. 2 A layered compact petrocalcic horizon (slab) (2) below an A horizon (containing pebbles of slab) (1) over a layered noncompact petrocalcic horizon (crust) (3) on a calcic horizon (4).
resulting in one or more superposed petrocalcic horizons. The vertical complete succession from the top is: finely layered, over thicker compact layers (slabs), over thick noncompact layers, over a massive horizon. There are four main types of vertical successions of petrocalcic horizons: – single massive horizons; – layered noncompact horizons, over unlayered horizons; – finely layered horizons, over layered noncompact horizons, over unlayered horizons; – finely layered horizons, over layered compact horizons, over layered noncompact horizons, over unlayered horizons. Petrocalcic horizons always have sharp upper boundaries and carbonate contents that decrease with depth. A gradual transition and discontinuous
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concentrations of carbonate mark the lower boundary of the petrocalcic horizon. The solum above the petrocalcic horizon is generally between 10 and 50 cm thick.
LATERAL DISTRIBUTION OF THE CALCIC AND PETROCALCIC HORIZONS As with vertical transitions, progressive lateral transitions frequently occur between different forms of calcic and petrocalcic horizons. From this, it can be concluded that the vertical and horizontal structures of calcium carbonate accumulation result from the same mechanisms.
Petrocalcic Horizons, Soils with
In a landscape, the lateral distribution of the calcic and petrocalcic horizons is mainly a function of topography and age. Along a slope or pediment, calcic horizon development increases downslope. In a complete toposequence (catena), differentiation progresses from a soil with minimal calcic horizon development upslope, to a soil with moderate calcic horizon development immediately downslope, and finally to soils with more and more strongly developed petrocalcic horizons, the different types and superposition of petrocalcic horizons appearing successively (Fig. 3). In time, calcic horizons evolve (Fig. 3) from diffuse carbonate distributions to discontinuous accumulations
Fig. 3 Relationships between calcic and petrocalcic horizons in space and time (North Morocco). The length of the sequences may vary between some tens and several hundreds of meters; the difference in altitude, between the old and recent Quaternary surfaces, is some tens of meters. (From Ref.[1].)
Copyright © 2006 by Taylor & Francis
Petrocalcic Horizons, Soils with
(pseudomycelia, cutans, nodules, or veins) to unlayered petrocalcic horizons to layered noncompact petrocalcic horizons to slab. The finely layered (ribboned) horizons can exist as soon as noncompact layered horizons appear. On the other hand, decarbonation of the A and B horizons above the calcic and petrocalcic horizons does not increase with age. It is only on the younger recent Quaternary surfaces that a small decarbonation can be observed as these surfaces age. However, this decarbonation does not increase on the older surfaces and, when petrocalcic horizons appear, the calcium carbonate content of the upper horizons may increase due to erosion and subsequent formation of the upper horizons from the calcrete. These facts confirm the following interpretations: There is a logical order of appearance of the calcic and petrocalcic accumulations and horizons; this logical order is the same in space, vertically and laterally, and in time. These accumulations and horizons are thus genetically linked, by toposequences and chronosequences. The vertical leaching of the calcium carbonate, which impoverishes the upper horizons in favor of the calcic and petrocalcic horizons, is a limited phenomenon; the major part of the calcium carbonate that accumulates in the soils comes from lateral redistributions. In arid and semiarid regions, which are the privileged domains of the petrocalcic horizons, calcic and petrocalcic horizons can occur in soils formed from noncalcareous or noncalcic rocks: this happens when landscapes upstream furnish calcium by lateral lixiviation. However, in very arid regions near the sea, very strong petrocalcic horizons occur in soils formed from noncalcareous, noncalcic rocks without possible upstream sources of calcium. So calcium carbonate can also arrive by air as calcareous dust and calcium from sea spray.
SOIL USE Petrocalcic horizons in soils at depths exchangeable > organic matter bonded >
Table 2 Concentrations and coefficient of variation of rare earth elements in different sludges Night soil sludgea (n = 10) Elements
Mean (mg kg1)
CV (%)
Sewage sludge (n = 14) Mean (mg kg1)
CV (%)
Food industry sludge (n = 10) Mean (mg kg1)
Chemical industry sludge (n = 10)
CV (%)
Mean (mg kg1)
CV (%)
La
3.39
37
6.70
47
0.89
72
2.46
98
Ce
6.98
44
14.10
58
1.83
77
2.69
105
Pr
0.82
38
1.48
46
0.22
82
0.48
95
Nd
3.18
34
6.00
47
0.91
82
2.04
98
Sm
0.53
36
1.02
40
0.17
81
0.36
95
Gd
0.53
34
1.18
45
0.17
79
0.48
101
Tb
0.07
45
0.16
36
0.03
81
0.06
103
Dy
0.39
53
0.93
33
0.14
76
0.39
110
Ho
0.07
54
0.19
32
0.03
79
0.09
119
Er
0.21
55
0.57
31
0.08
73
0.26
118
Tm
0.03
52
0.08
26
0.01
81
0.03
112
Yb
0.20
58
0.54
31
0.09
83
0.19
109
Lu
0.03
56
0.08
31
0.01
84
0.03
105
a
Feces and urine of humans. (From Ref.[5].)
Copyright © 2006 by Taylor & Francis
Rare Earth Elements
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Table 3 Mean content of REEs in soils extracted by Na2O2=NaOH (n ¼ 467)
Light REEs
Table 5 Total concentration of rare earth elements in plants (mg kg1)
Total contents (mg kg1) and ratios
Species
Content (mg kg1)
Heavy REEs
Content (mg kg1)
La
41.2
Gd
4.8
Total REE (T)
172.8
Ce
73.4
Tb
0.7
Light REE (L)
156.0
Pr
7.3
Dy
4.4
Heavy REE (H)
16.8
Nd
27.5
Ho
0.9
L=H
9.3
Sm
5.6
Er
2.7
L=T
0.9
Eu
1.1
Tm
0.4
Yb
2.5
Lu
0.4
(From Ref.[1].)
Fe=Mn oxide bonded REEs.[9] The formation of bridged hydroxo complexes is probably the dominant sorption mechanism to clay minerals.[14] Clay type, pH, CEC, organic matter, and amorphous iron content regulate the adsorption kinetics of REEs.[1,2,9] Langmuir and Freundlich equations were found to describe precisely the absorption of REEs in soils.[1,15]
Rice Wheat Corn Cucumber Leek Spinach Cauliflower Lotus root Tomato Chinese cabbage Pepper Potato Cabbage Mushroom Orange Litchi Grape Longan Banana Apple Pear Watermelon Sugarcane Peach
n
Min (mg kg1)
Max (mg kg1)
319 440 139 41 33 41 61 31 64 67 31 34 38 33 41 30 61 30 33 62 34 37 27 4