Modelling the three-dimensional spatial distribution of soil organic carbon (SOC) at the regional scale (Flanders, Belgium)

Meersmans, Jeroen; van Wesemael, B.; De Ridder, F.; Van Molle, M.

doi:10.1016/j.geoderma.2009.05.015

Article (Scientific journals)

Modelling the three-dimensional spatial distribution of soil organic carbon (SOC) at the regional scale (Flanders, Belgium)

Meersmans, Jeroen; van Wesemael, B.; De Ridder, F. et al.

2009 • In Geoderma, 152 (1-2), p. 43-52

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https://hdl.handle.net/2268/264894

DOI
10.1016/j.geoderma.2009.05.015

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Keywords :

Belgium; Depth; Land use; Soil organic carbon; Soil type; Vertical distribution; Clay minerals; Global warming; Organic carbon; Programmable logic controllers; Silt; Size distribution; Three dimensional; Geologic models; Benelux; Eurasia; Europe; Flanders; Western Europe

Abstract :

[en] The rate of exchange of CO2 between the soil and the atmosphere depends on the stability of the organic carbon stored in the soil. Recent studies show that carbon stored in the subsoil is characterised by larger turnover times than the carbon stored in the topsoil. Consequently, identification of the depth at which high/low amounts of SOC are stored is essential for applying sustainable management of the soil in the light of global warming and related threats. This study investigates the depth distribution of SOC in relation to land use and soil type based on a large dataset for Flanders (Belgium). Soil type determines the SOC content along the entire profile. On the contrary, land use appears to have a strong influence on SOC content in the top layers of the profile, but doesn't play a significant role at the bottom of the profile (> 1 m depth). SOC content near the surface of the profile is remarkably higher in fine (clay) textured soils than in coarse (sand) textured soils and tends to increase by increasing soil wetness under sand and silt textured soils. SOC at the bottom of the profile increases as well by increasing soil wetness, but only in fine (clay and silt) textured soils. The rate of decline of SOC content with depth depends on texture and land use. Under forest this decline is remarkably fast, although less so in the more sandy soil types. The overall model predicts the distribution of SOC density by depth using land use and soil type information and allows in its integrated form the estimation of SOC stocks that can be represented on SOC maps until a reference depth free of choice. Applying this model, based on a three-dimensional spatial distribution approach, the total amount of SOC stored in Flanders is calculated at 62.20 ± 0.72 Mt C for the top 0.3 m and 103.19 ± 1.27 Mt C for the top 1 m. © 2009 Elsevier B.V. All rights reserved.

Disciplines :

Physical, chemical, mathematical & earth Sciences: Multidisciplinary, general & others

Author, co-author :

Meersmans, Jeroen ; Université de Liège - ULiège > Département GxABT > Analyse des risques environnementaux

van Wesemael, B.; Geography Department, Université Catholique de Louvain, Place Louis Pasteur 3, 1347 Louvain-la-neuve, Belgium

De Ridder, F.; VITO - Energy Technology, Boeretang 200, 2400 Mol, Belgium

Van Molle, M.

Language :

English

Title :

Modelling the three-dimensional spatial distribution of soil organic carbon (SOC) at the regional scale (Flanders, Belgium)

Publication date :

2009

Journal title :

Geoderma

ISSN :

0016-7061

eISSN :

1872-6259

Publisher :

Elsevier, Netherlands

Volume :

152

Issue :

1-2

Pages :

43-52

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 08 November 2021

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Bibliography

Al-Adamat R., Rawajfih Z., Easter M., Paustian K., Coleman K., Milne E., Falloon P., Powlson D.S., and Batjes N.H. Predicted soil organic carbon stocks and changes in Jordan between 2000 and 2030 made using the GEFSOC modelling system. Agriculture Ecosystems and Environment 122 1 (2007) 35-45
Ameryckx J.B., Verheye W., and Vermeire R. Bodemkunde. Gent (1995)
Andrews S.S., Karlen D.L., and Cambardella C.A. The soil management assessment framework: a quantitative soil quality evaluation method. Soil Science Society of America Journal 68 6 (2004) 1945-1962
Baisden W.T., and Parfit R.L. Bomb C-14 enrichment indicates decadal C pool in deep soil?. Biochemistry 85 1 (2007) 59-68
Balesdent J., Chenu C., and Balabane M. Relationship of soil organic matter dynamics to physical protection and tillage. Soil & Tillage Research 53 3-4 (2000) 215-230
Batjes N.H. Effects of mapped variation in soil conditions on estimates of soil carbon and nitrogen stocks for South America. Geoderma 97 1-2 (2000) 135-144
Bhattacharyya T., Pal D.K., Easter M., Batjes N.H., Milne E., Gajbhiye K.S., Chandran P., Ray S.K., Mandal C., Paustian K., Williams S., Killian K., Coleman K., Falloon P., and Powlson D.S. Modelled soil organic carbon stocks and changes in the Indo-Gangetic Plains, India from 1980 to 2030. Agriculture Ecosystems and Environment 122 1 (2007) 84-94
Bohn H.L. Estimate of organic-carbon in world soils 2. Soil Science Society of America Journal 46 5 (1982) 1118-1119
Boucneau G., Van Meirvenne M., and Hofman G. Comparing pedotransfer functions to estimate bulk density in northern Belgium. Pedologie - Themata 5 (1998) 67-70
Cerri C.E.P., Easter M., Paustian K., Killian K., Coleman K., Bernoux M., Falloon P., Powlson D.S., Batjes N.H., Milne E., and Cerri C.C. Predicted soil organic carbon stocks and changes in the Brazilian Amazon between 2000 and 2030. Agriculture Ecosystems and Environment 122 (2007) 58-72
Davidson E.A. Spatial covariation of soil organic carbon, clay content and drainage class at a regional scale. Landscape Ecolology 10 (1995) 349-362
Dawson J.J.C., Godsiffe E.J., Thompson I.P., Ralebitso-Senior T.K., Killham K.S., and Paton G.I. Application of biological indicators to assess recovery of hydrocarbon impacted soils. Soil Biology & Biochemistry 39 1 (2007) 164-177
Don A., Schumacher J., Scherer-Lorenzen M., Scholten T., and Schulze E.D. Spatial and vertical variation of soil carbon at two grassland sites - implications for measuring soil carbon stocks. Geoderma 141 (2007) 272-282
Dousset S., Chauvin C., Durlet P., and Thevenot M. Transfer of hexazinone and glyphosate through undisturbed soil columns in soils under Christmas tree cultivation. Chemosphere 57 4 (2004) 265-272
Feller C., and Beare M.H. Physical control of soil organic matter dynamics in the tropics. Geoderma 79 1-4 (1997) 69-116
Fontaine S., Barot S., Barré P., Bdioui N., Mary B., and Rumpel C. Stability of organic carbon in deep soil layers controlled by fresh carbon supply. Nature 450 (2007) 277-280
Gal A., Vyn T.J., Micheli E., Kladivko E.J., and McFee W.W. Soil carbon and nitrogen accumulation with long-term no-till versus moldboard plowing overestimated with tilled-zone sampling depths. Soil & Tillage Research 96 (2007) 42-51
Gill R., Burke I.C., Milchunas D.G., and Lauenroth W.K. Relationship between root biomass and soil organic matter pools in the shortgrass steppe of eastern Colorado. Ecosystems 2 3 (1999) 226-236
Gundersen P., Callesen I., and de Vries W. Nitrate leaching in forest ecosystems is related to forest floor C/N ratios. Environmental Pollution 102 (1998) 403-407
Hilinski T.E. Implementation of Exponential Depth Distribution of Organic Carbon in the CENTURY Model (2001). http://www.nrel.colostate.edu/projects/century5/reference/html/Century/exp www.nrel.colostate.edu/projects/century5/reference/html/Century/exp-c-distrib.htm.
Jackson R.B., Schenk H.J., Jobbagy E.G., Canadell J., Colello G.D., Dickinson R.E., Field C.B., Friedlingstein P., Heimann M., Hibbard K., Kicklighter D.W., Kleidon A., Neilson R.P., Parton W.J., Sala O.E., and Sykes M.T. Belowground consequences of vegetation change and their treatment in models. Ecological Applications 10 2 (2000) 470-483
Jarvis N., Larsbo M., Roulier S., Lindahl A., and Persson L. The role of soil properties in regulating non-equilibrium macropore flow and solute transport in agricultural topsoils. European Journal of Soil Science 58 1 (2007) 282-292
Jobbagy E.G., and Jackson R.B. The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecological Applications 10 2 (2000) 423-436
Jones R.J.A., Hiederer R., Rusco E., Loveland P., and Montanarella L. The map of organic carbon in topsoils in Europe, Version 1.2, September 2003: explanation of Special Publication Ispra 2004 No.72 (S.P.I.04.72). European Soil Bureau Research Report No.17 (2004), Office for Official Publications of the European Communities, Luxembourg
Kamoni P.T., Gicheru P.T., Wokabi S.M., Easter M., Milne E., Coleman K., Falloon P., Paustian K., Killian K., and Kihanda F.M. Evaluation of two soil carbon models using two Kenyan long term experimental datasets. Agriculture Ecosystems and Environment 122 1 (2007) 95-104
Kern J.S. Spatial patterns of soil organic-carbon in the contiguous United States. Soil Science Society of America Journal 58 2 (1994) 439-455
Lafrance P., and Banton O. Implication of spatial variability of organic-carbon on predicting pesticide mobility in soil. Geoderma 65 3-4 (1995) 331-338
Lettens S., Van Orshoven J., van Wesemael B., and Muys B. Soil organic and inorganic carbon contents of landscape units in Belgium derived using data from 1950 to 1970. Soil Use and Management 20 1 (2004) 40-47
Lettens S., van Orshoven J., van Wesemael B., Muys B., and Perrin D. Soil organic carbon changes in landscape units of Belgium between 1960 and 2000 with reference to 1990. Global Change Biology 11 12 (2005) 2128-2140
Liebens J., and VanMolle M. Influence of estimation procedure on soil organic carbon stock assessment in Flanders, Belgium. Soil Use and Management 19 4 (2003) 364-371
Lindahl A.M.L., Kreuger J., Stentröm J., Gärdenäs A.I., Alavi G., Roulier S., and Jarvis N.J. Stochastic modeling of diffuse pesticide losses from a small agricultural catchment. Journal of Environmental Quality 34 4 (2005) 1174-1185
Manrique L.A., and Jones C.A. Bulk density of soils in relation to soil physical and chemical properties. Soil Science Society of America Journal 55 2 (1991) 476-481
Meersmans, J., 2008. www.jeroenmeersmans.be/research/publications/depth3Dmod.
Meersmans J., De Ridder F., Canters F., De Baets S., and Van Molle M. A multiple regression approach to assess the spatial distribution of Soil Organic Carbon (SOC) at the regional scale (Flanders, Belgium). Geoderma 143 1-2 (2008) 1-13
Meersmans, J., van Wesemael, B., De Ridder, F., Fallas Dotti, M., De Baets, S., Van Molle, M., in press. Changes in organic carbon distribution with depth in agricultural soils in northern Belgium, 1960-2006. Global Change Biology. doi:10.1111/j.1365-2486.2009.01855.x.
Milne E., Al Adamat R., Batjes N.H., Bernoux M., Bhattacharyya T., Cerri C.C., Cerri C.E.P., Coleman K., Easter M., Falloon P., Feller C., Gicheru P., Kamoni P., Killian K., Pal D.K., Paustian K., Powlson D.S., Rawajfih Z., Sessay M., Williams S., and Wokabi S. National and sub-national assessments of soil organic carbon stocks and changes: the GEFSOC modelling system. Agriculture Ecosystems and Environment 122 1 (2007) 3-12
Mokany K., Raison R.J., and Prokushkin A.S. Critical analysis of root:shoot ratios in terrestrial biomes. Global Chang Biology 12 (2006) 84-96
Ondersteunend Centrum GIS-Vlaanderen. Digital Soil Map of Flanders (2001), VLM (Vlaamse Land Maatschappij), Brussels
Ondersteunend Centrum GIS-Vlaanderen. Digital Land Use Map of Flanders (2002), VLM (Vlaamse Land Maatschappij), Brussels
Omonode R.A., and Vyn T.J. Vertical distribution of soil organic carbon and nitrogen under warm-season native grasses relative to croplands in west-central Indiana, USA. Agriculture Ecosystems and Environment 117 2-3 (2006) 159-170
Pattison A.B., Moody P.W., Badcock K.A., Smith L.J., Armour J.A., Rasiah V., Cobon J.A., Gulino L.-M., and Mayer R. Development of key soil health indicators for the Australian banana industry. Applied Soil Ecology 40 1 (2008) 155-164
Poissant L., Beauvais C., Lafrance P., and Deblois C. Pesticides in fluvial wetlands catchments under intensive agricultural activities. Science of the Total Environment 404 1 (2008) 182-195
Razafimbelo T.M., Albrecht A., Oliver R., Chevallier T., Chapuis-Lardy L., and Feller C. Aggregate associated-C and physical protection in a tropical clayey soil under Malagasy conventional and no-tillage systems. Soil & Tillage Research 98 2 (2008) 140-149
Richards J.E., and Webster C.P. Denitrification in the subsoil of the Broadbalk continuous wheat experiment. Soil Biology & Biochemistry 31 5 (1999) 747-755
Sleutel S., De Neve S., and Hofman G. Estimates of carbon stock changes in Belgian cropland. Soil Use and Management 19 2 (2003) 166-171
Slobodian N., Van Rees K., and Pennock D. Cultivation-induced effects on belowground biomass and organic carbon. Soil Science Society of America Journal 66 3 (2002) 924-930
Soil Survey Staff. Soil survey manual, United States Department of Agriculture. U.S. Dept. Agricultural Handbook, 18, Washington, D.C (1951)
Tan Z.X., Lal R., Smeck N.E., and Calhoun F.G. Relationships between surface soil organic carbon pool and dite variables. Geoderma 121 (2004) 187-195
Trumbore S. Age of soil organic matter and soil respiration: radiocarbon constraints on belowground C dynamics. Ecological Applications 10 2 (2000) 399-411
Van Meirvenne M., Pannier J., Hofman G., and Louwagie G. Regional characterization of the long-term change in soil organic carbon under intensive agriculture. Soil Use Manage 12 (1996) 86-94
Van Orshoven J., Maes J., Vereecken H., Feyen J., and Didal R. A structured database of Belgian soil profile data. Pedologie 38 (1988) 191-206
Walkley A., and Black I.A. An examination of Degtjareff method for determining soil organic matter and a proposed modification of the chromic acid titration method. Soil Science 37 (1934) 29-37
Wang S., Huang M., Mickler R.A., Li K., and Ji J. Vertical distribution of soil organic carbon in China. Environmental Management 33 (2004) 200-209
Zinn Y.L., Lal R., and Resck D.V.S. Texture and organic carbon relations described by a profile pedotransfer function for Brazilian Cerrado soils. Geoderma 127 1-2 (2005) 168-173