Claypan

Claypan is a dense, compact, slowly permeable layer in the subsoil.^[1] It has a much higher clay content than the overlying material, from which it is separated by a sharply defined boundary. The dense structure restricts root growth and water infiltration. Therefore, a perched water table might form on top of the claypan.^[2] In the Canadian classification system, claypan is defined as a clay-enriched illuvial B (Bt) horizon.^[3]

Location[edit]

Claypan is present in a wide area of the central United States (about 4 million ha) across multiple states such as Kansas, Oklahoma, and Illinois.^[2] It can also be found in Australia throughout the south-west Queensland.^[4]

Formation[edit]

Claypan is formed in different parent materials depending on geological locations, such as floodplains. The formation of the claypan relates to a lack of vegetation coverage, soil particle size distribution, and high rainfall. The lack of vegetation coverage makes soil become more susceptible to raindrop attacks. When the raindrops hit on bare soil with high energy, the fine sand, silt, and clay particles are re-arranged to plug all the pore spaces. When all the pores are filled, a packed layer is formed to limit the water infiltration.^[4]

Characteristics[edit]

The dominant material is the montmorillonite clay material which has a high swell and shrinks characteristics depending on the soil water content. In the dry season, evaporation moves water from the deep horizon toward the soil surface through capillary action. The water removal results in shrinkage of clay, and the soil becomes dry and hard. In the wet season, high precipitation leads to a swell of clay to absorb water. The high moisture content results in wet and sticky clay texture. When the clay swells, the low saturated hydraulic conductivity prevents the vertical water infiltration to the deeper soil horizon. It leads to water perches above the claypan layer.^[5]

The water permeability is restricted in the claypan layer resulting in low soil aeration. The water-holding capability of the claypan is high. However, most of the stored water is not available for the plant since water evaporates frequently and soil pore size is tiny.^[6]

Since the claypan is acidic and clay-rich, there is high sorption of Al, K and Fe oxides to clay minerals. Therefore, the claypan contains a cations-dominated zone that leads to a relatively high cation exchange capacity (CEC) to absorb and retain nutrients.^[7]

The concentration of extractable potassium positively relates to clay content. There is a relatively high extractable potassium content in the claypan due to the accumulation of cations. The high content of aluminium oxidates, and iron oxidates attract phosphorus to clay particles which increases the phosphorus content in the soil.^[8]

Influences on plants[edit]

The major negative influences of claypan on plants are root restriction, available water limitation and nutrient limitation. The dense structure of the claypan restricts root development.

Plants with shallow roots, might not withstand the soil contraction forces due to the shrinkage of clay in the dry season. The low water infiltration rate and hydraulic conductivity may lead to a perched water table form on top of the claypan layer. Water in the perched water table evaporates instead of uptake by plants, especially in the dry season. In the wet season with high precipitation, water can penetrate throughout the soil. However, the low aeration in saturated soil may result in root rots that reduce the stability of plants.^[9]

The acidic, clay-rich characteristics of the claypan lead to phosphorus (P) sorption to clay minerals. Even though the total P content in the claypan is relatively high, they are strongly attracted by the clay particles that are not available for plant use. Therefore, a high amount of P fertilizer is required to increase the available P for plant absorption. Different from P, the high content of potassium (K) in the claypan is available for plant use which reduces the application of potassium fertilizer.^[7]

Risk of soil erosion[edit]

Soil with a claypan layer is highly vulnerable to soil erosion. The low water infiltration rate and the perched water table form on top of the claypan layer largely increase the surface runoff during precipitation with a long duration or high intensity. The runoff water can remove the topsoil with mostly organic matter. It will further reduce the nutrient availability for plants.^[1]

References[edit]

^ ^a ^b Conway, L. S.; Yost, M. A.; Kitchen, N. R.; Sudduth, S. (2017). "Using topsoil thickness to improve Site‐Specific phosphorus and potassium management on claypan soil". Agronomy Journal. 109 (5): 2291–2301. doi:10.2134/agronj2017.01.0038.
^ ^a ^b Hsiao, C.; Sassenrath, G. F.; Zeglin, L. H.; Hettiarachchi, G. M.; Rice, C. W. (2018). "Vertical changes of soil microbial properties in claypan soils". Soil Biology & Biochemistry. 121: 154–164. doi:10.1016/j.soilbio.2018.03.012. S2CID 90573070.
^ Government of Canada (13 December 2013). "Glossary of terms in soil science".
^ ^a ^b Williams, K.; Biggs, A. "Formation of clay pans in South-West Queensland, Australia" (PDF).
^ Rao, S.M. (2011). "Wetting and Drying, Effect on Soil Physical Properties". Encyclopedia of Agrophysics. Encyclopedia of Earth Sciences Series. pp. 992–996. doi:10.1007/978-90-481-3585-1_189. ISBN 978-90-481-3584-4.
^ Sadler, E.J.; Lerch, R.N.; Kitchen, N.R.; Anderson, S.H.; Baffaut, C.; Sudduth, K.A. (2015). "Long-term agro-ecosystem research in the central Mississippi River Basin, USA: Introduction, establishment, and overview". J. Environ. Qual. 44 (1): 3–12. doi:10.2134/jeq2014.11.0481. PMID 25602315.
^ ^a ^b Jamison, V.C.; Smith, D.D.; Thornton, J.F. Soil and water research on a claypan soil. Washington, DC: USDA-ARS.
^ Congreves, K. A.; Smith, J. M.; Németh, D. D.; Hooker, D.; Van Eerd, L. L. (2014). "Soil organic carbon and land use: Processes and potential in Ontario's long-term agro-ecosystem research sites". Canadian Journal of Soil Science. 94 (3): 317–336. doi:10.4141/cjss2013-094. hdl:10214/21250.
^ Scharf, P.; Miles, R.; Nathan, M. P and K fixation by Missouri soils. Missouri soil fertility and fertilizers research update. Columbia: Univ. of Missouri.

[Conway_et_al_2017-1] Conway, L. S.; Yost, M. A.; Kitchen, N. R.; Sudduth, S. (2017). "Using topsoil thickness to improve Site‐Specific phosphorus and potassium management on claypan soil". Agronomy Journal. 109 (5): 2291–2301. doi:10.2134/agronj2017.01.0038.

[auto1-2] Hsiao, C.; Sassenrath, G. F.; Zeglin, L. H.; Hettiarachchi, G. M.; Rice, C. W. (2018). "Vertical changes of soil microbial properties in claypan soils". Soil Biology & Biochemistry. 121: 154–164. doi:10.1016/j.soilbio.2018.03.012. S2CID 90573070.

[3] Government of Canada (13 December 2013). "Glossary of terms in soil science".

[auto-4] Williams, K.; Biggs, A. "Formation of clay pans in South-West Queensland, Australia" (PDF).

[5] Rao, S.M. (2011). "Wetting and Drying, Effect on Soil Physical Properties". Encyclopedia of Agrophysics. Encyclopedia of Earth Sciences Series. pp. 992–996. doi:10.1007/978-90-481-3585-1_189. ISBN 978-90-481-3584-4.

[6] Sadler, E.J.; Lerch, R.N.; Kitchen, N.R.; Anderson, S.H.; Baffaut, C.; Sudduth, K.A. (2015). "Long-term agro-ecosystem research in the central Mississippi River Basin, USA: Introduction, establishment, and overview". J. Environ. Qual. 44 (1): 3–12. doi:10.2134/jeq2014.11.0481. PMID 25602315.

[auto2-7] Jamison, V.C.; Smith, D.D.; Thornton, J.F. Soil and water research on a claypan soil. Washington, DC: USDA-ARS.

[8] Congreves, K. A.; Smith, J. M.; Németh, D. D.; Hooker, D.; Van Eerd, L. L. (2014). "Soil organic carbon and land use: Processes and potential in Ontario's long-term agro-ecosystem research sites". Canadian Journal of Soil Science. 94 (3): 317–336. doi:10.4141/cjss2013-094. hdl:10214/21250.

[9] Scharf, P.; Miles, R.; Nathan, M. P and K fixation by Missouri soils. Missouri soil fertility and fertilizers research update. Columbia: Univ. of Missouri.

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v t e Soil classification
World Reference Base for Soil Resources (1998–)	Acrisols Alisols Andosols Anthrosols Arenosols Calcisols Cambisols Chernozem Cryosols Durisols Ferralsols Fluvisols Gleysols Gypsisols Histosol Kastanozems Leptosols Lixisols Luvisols Nitisols Phaeozems Planosols Plinthosols Podzols Regosols Retisols Solonchaks Solonetz Stagnosol Technosols Umbrisols Vertisols
USDA soil taxonomy	Alfisols Andisols Aridisols Entisols Gelisols Histosols Inceptisols Mollisols Oxisols Spodosols Ultisols Vertisols
Other systems	FAO soil classification (1974–1998) Unified Soil Classification System AASHTO Soil Classification System Référentiel pédologique (French classification system) Canadian system of soil classification Australian Soil Classification Polish Soil Classification 1938 USDA soil taxonomy List of U.S. state soils List of vineyard soil types
Non-systematic soil types	Sand Silt Clay Loam Topsoil Subsoil Soil crust Claypan Hardpan Gypcrust Caliche Parent material Pedosphere Laimosphere Rhizosphere Bulk soil Alkali soil Bay mud Blue goo Brickearth Brown earth Calcareous grassland Dark earth Dry quicksand Duplex soil Eluvium Expansive clay Fill dirt Fuller's earth Hydrophobic soil Loess Lunar soil Martian soil Mud Muskeg Paleosol Peat Prime farmland Serpentine soil Spodic soil Stagnogley Subaqueous soil Takir Terra preta Terra rossa Tropical peat Yedoma
Types of soil

Claypan

Location[edit]

Formation[edit]

Characteristics[edit]

Influences on plants[edit]

Risk of soil erosion[edit]

See also[edit]

References[edit]

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