Abstract
World soils and terrestrial ecosystems have been a source of atmospheric abundance of CO2 ever since settled agriculture began about 10–13 millennia ago. The amount of CO2-C emitted into the atmosphere is estimated at 136 ± 55 Pg from terrestrial ecosystems, of which emission from world soils is estimated at 78 ± 12 Pg. Conversion of natural to agricultural ecosystems decreases soil organic carbon (SOC) pool by 30–50% over 50–100 years in temperate regions, and 50–75% over 20–50 years in tropical climates. The projected global warming, with estimated increase in mean annual temperature of 4–6°C by 2100, may have a profound impact on the total soil C pool and its dynamics. The SOC pool may increase due to increase in biomass production and accretion into the soil due to the so-called “CO2 fertilization effect”, which may also enhance production of the root biomass. Increase in weathering of silicates due to increase in temperature, and that of the formation of secondary carbonates due to increase in partial pressure of CO2 in soil air may also increase the total C pool. In contrast, however, SOC pool may decrease because of: (i) increase in rate of respiration and mineralization, (ii) increase in losses by soil erosion, and (iii) decrease in protective effects of stable aggregates which encapsulate organic matter. Furthermore, the relative increase in temperature projected to be more in arctic and boreal regions, will render Cryosols under permafrost from a net sink to a net source of CO2 if and when permafrost thaws. Thus, SOC pool of world soils may decrease with increase in mean global temperature. In contrast, the biotic pool may increase primarily because of the CO2 fertilization effect. The magnitude of CO2 fertilization effect may be constrained by lack of essential nutrients (e.g., N, P) and water. The potential of SOC sequestration in agricultural soils of Europe is 70–190 Tg C yr−1. This potential is realizable through adoption of recommended land use and management, and restoration of degraded soils and ecosystems including wetlands.
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References
Agren GI, Hyvonen R (2003) Changes in carbon stores in Swedish forest soils due to increased biomass harvest and increased temperatures analysed with a semi-empirical model. For Ecol Manage 174:25–37
Andren O, Katterer T, Karlsson T (2004) ICBM regional mode for estimations of dynamics of agricultural soil carbon pools. Nutr Cycl Agroecosyst 70:231–239
Arnalds Ó, Gudbergsson G, Gudmundsson J (2000) Carbon sequestration and reclamation of severely degraded soils of Iceland. Icel Agr Ju 13:87–97
Berzseny Z, Gyrffy B (1997) Effect of crop rotation and fertilization on maize and wheat yield stability in long-term experiments. Agrok mas Talajtan 46:377–398
Bottner P, Coûteaux MM, Vallejo VR (1995) Soil organic matter in Mediterranean-type ecosystems and global climate changes: a case study – the soils of the Mediterranean Basin. In: Moreno JM, Oechel WC (eds) Global change and Mediterranean type ecosystems. Springer-Verlag, New York, pp 306–325
Bouma J, Varallyay G, Batjes NH (1998) Principal land use changes anticipated in Europe. Agric Ecosyst Env 67:103–119
Buckland SM, Thompson K, Hodgson JG, Grime JP (2001) Grassland invasions: effects of manipulations of climate and management. J Appl Ecol 38:301–309
Callesen I, Liski J, Raulund-Rasmussen K, Olsson MT, Tau-Strand L, Veserdal L, Westman CJ (2003) Soil carbons stores in Nordic well-drained forest soils-relationships with climate and texture class. Glob Chang Biol 9:358–370
Cheddadi R, Guiot J, Jolly D (2001) The Mediterranean vegetation: what if the atmospheric CO2 increased? Landsc Ecol 16:667–675
Cox RM, Betts RA, Jones CD, Spall SA, Totterdell IJ (2000) Acceleration of global warming due to carbon-cycle feedbacks in a coupled climate model. Nature 408:184–187
Dalias P, Anderson JM, Bottner P, Coûteaux M-M (2001) Long-term effects of temperature on carbon mineralization processes. Soil Biol Biochem 33:1049–1057
Dixon RK, Brown S, Houghton RA, Solomon AM, Trexler MC, Wisniewski J (1994) Carbon pools and flux of global forest ecosystems. Science 263:185–190
Dooley JJ, Dahowski RT, Davidson CL, Wise MA, Gupta N, Kim SH, Malone EL (2006) Carbon dioxide capture and geologic storage. Battelle, MD, p 67
Dregne HE, Chou N-T (1992) Global desertification: dimensions and costs. In: Dregne HE (eds) Degradation and Restoration of Arid Lands. Texas Tech University, Lubbock, pp 249–281
Duckworth JC, Bunce RGH, Malloch AJC (2000) Modelling the potential effects of climate change on calcareous grasslands in Atlantic Europe. J Biogeo 27:347–358
Eckersten H, Blomback K, Katterer T, Nyman P (2001) Modelling C, N, water and heat dynamics in winter wheat under climate change in southern Sweden. Agric Ecosyst Env 86:221–235
Edwards AP, Bremmer JM (1967) Microaggregatesd in soils. J Soil Sci 18:64–73
FAO (1998) Production yearbook in agriculture. FAO, Rome
FAO (2000) Production yearbook in agriculture. FAO, Rome
Feely R, Sabine CL, Lee K, Berelson W, Kleypass J, Fabry VJ, Millero FL (2004) Impact of anthropogenic CO2 on the CaCO3 system in the oceans. Science 305:362–366
Fullen MA, Auerswald K (1998) Effect of grass ley set-aside on runoff, erosion and organic matter levels in sandy soil in east Shropshire, UK. Soil Till Res 46:41–49
Gislason SR (2005) Chemical weathering, chemical denudation and the CO2 budget for Iceland. In: Caseldine C, Russell A, Hardardottir J, Knudsen O (eds) Iceland: modern processes and part environments, developments in quaternary science 5. Elsevier, Amsterdam, pp 289–307
Gudmundson T, Bjornsson H, Thorvaldsson G (2004) Organic carbon accumulation and pH changes in an Andic Gleysol under a long-term fertilizer experiment in Iceland. Catena 56:211–224
Hansen EM, Christensen BT, Jensen LS, Kristensen K (2004) Carbon Sequestration in soil beneath long-term Miscanthus plantations as determined by 13C abundance. Biomass Bioenergy 26:97–105
Hayes MHB (2006) Biochar and biofuels for a brighter future. Nature 443:144
Hendry GAF, Grime JP (1990) Natural vegetation. In: Cannell MGR, Hooper MD (eds) The greenhouse effect and the terrestrial ecosystems in the UK. HMSO, London, pp 27–31
Hennessy KJ, Gregory JM, Mitchell JFB (1997) Changes in daily precipitation under enhanced greenhouse conditions. Clim Dyn 13:667–680
Intergovernment Panel on Climate Change (IPCC) (1996) Climate change 1995. Impacts, adaptations and mitigation of climate change scientific-technical analyses. Cambridge University Press, NY, 879 pp
Intergovernment Panel on Climate Change (IPCC) (2000) Land use, land use change and forestry intergovernment panel on climate change. Cambridge University Press, UK, 377 pp
Janssens IA, Freibauer A, Ciais P, Smith P, Nabburs GA, Folberth G, Schlamadinger B, Hutjes RWA, Cenlemans R, Detley Schulze E, Valentinim R, Dolman JA (2003) Europe’s terrestrial biosphere absorbs 7 to 12% of European anthropogenic CO2 emissions. Science 300:1538–1542
Johnston AE (1973) The effects of ley and arable cropping systems on the amount of organic matter in the Rothamstead and Woburn Ley-Arable Experiments. Rothamstead Report for 1972, Part 2, pp 131–159
Karlsson L, Andren O, Katterer T, Mattsson L (2003) Management effects on topsoil carbon and nitrogen in Swedish long-term field experiments – budget calculations with and without humus pool dynamics. Eur J Agron 20:137–147
Katterer T, Andren O, Persson J (2004) The impact of altered management on long-term agricultural soil carbon stocks – a Swedish case study. Nutr Cycl Agroecosyst 70:179–187
Kleemola J, Pehu E, Peltonen-Sainio P, Karvonen T (1995) Modeling the impact of climate change on growth of spring barley in Finland. J Biogeogr 22:581–590
Kolchugina TP, Vinson TS (1993a) Comparison of tow methods to assess the carbon budget of forest biomes in the former Soviet Union. Water Air Soil Pollut 70:207–221
Kolchugina TP, Vinson TS (1993b) Equilibrium analysis of the carbon pools and fluxes of forest biomes in the former Soviet Union. Can J For Res 23:81–88
Kristiansen SM, Hansen EM, Jensen LS, Christensen BT (2005) Natural 13C abundance and carbons storage in Danish soils under continuous silage maize. Eur J Agron 22:107–117
Lal R (2004) Soil carbon sequestration impacts on global climate change and food security. Science 304:1623–1627
Lal R, Kimble JM, Follett RF, Cole CV (1998) The potential of U.S. cropland to sequester carbon and mitigate the greenhouse effect. CRC/Lewis Publishers, Boca Raton, 128 pp
Lamb D, Erskine PD, Parrota JA (2005) Restoration of degraded tropical forest landscapes. Science 310:1628–1632
Liski J, Perruchoud D, Karjalainen T (2002) Increasing carbon stocks in the forest soils of western Europe. For Ecol Manage 169:159–175
Lohila A, Aurela M, Regina K, Laurila T (2003) Soil and total ecosystem respiration in agricultural fields: effect of soil and crop type. Plant Soil 251:303–317
Lorenz K, Lal R (2005) The depth distribution of soil organic carbon in relation to land use and management, and the potential of C sequestration in sub-soil horizons. Adv Agron 88:36–66
Lump LR (2002) Reducing uncertainty about CO2 as a climate driver. Nature 419:188–190
Marris E (2006) Putting the carbon back. Black is the new green. Nature 442:624–626
Nabuurs GJ, Päivinen R, Sikkema R, Mohren GMJ (1997) The role of European forests in the global carbon cycle – a review. Biomass Bioenergy 13:345–358
Nilsson LG (1986) Data of yield and soil analysis in the long-term soil fertility experiments. J Royal Swed Acad Agric For Supp 18:32–70
Oldeman LR (1994) The global extent of soil degradation. In: Greenland DJ, Szabolcs I (eds) Soil Resilience and Sustainable Land Use. CAB International, Wallingford, pp 99–118
Oleson JE, Rubaek GH, Heidmann T, Hansen S, Borgensen CD (2004) Effect of climate change on greenhouse gas emissions from arable crop rotations. Nutr Cycl Agroecosyst 70:147–160
Oren R, Ellsworth DS, Johnsen KH, Phillips N, Ewers BE, Maier C, Schäfer KVR, McCarthy H, Hendrey G, McNulty SG, Katul GG (2001) Soil fertility limits carbon sequestration by forest ecosystems in CO2-enriched atmosphere. Nature 411:469–472
Ozenda P, Borel J-L (1990) The possible responses of vegetation to a global climate change. Scenario for Western Europe with special reference to the Alps. In: Boer M, de Groot RS (eds) Landscape-ecological impact of climate change. Proceedings of European Conference, Lunteren, pp 221–249
Pacala S, Socolow R (2004) Stabilization wedges: solving the climate problem for the next 50 years with current technologies. Science 305:968–972
Peng CH, Guiot J, Van Campo E, Cheddadi R (1995) Temporal and spatial variations of terrestrial biomes and carbon storage since 13,000 years BP in Europe: reconstruction from pollen data and statistical models. Water Air Soil Pollut 82:375–390
Prentice KC, Fung IY (1990) The sensitivity of terrestrial carbon storage to climate change. Nature 346:48–50
Ruddiman WF (2003) The anthropogenic greenhouse era began thousands of years ago. Clim Change 61:292–292
Ruddiman WF (2005) Plows, plagues and petroleum: how humans took control of climate? Princeton University Press, Princeton
Rumpel C, Chaplot V, Planchon O, Bernadou J, Valentin C, Mariotti A (2006a) Preferential erosion of black carbon on steep slopes with slash and burn agriculture. Catena 65:30–40
Rumpel C, Alexis M, Chabbi A, Chaplot V, Rasse DP, Valentin C, Mariotti A (2006b) Black carbon contribution to soil organic matter composition in tropical sloping land under slash and burn agriculture. Geoderma 130:35–46
Sabine CL, Feely RA, Gruber N, Key RM, Lee K, Bullister JL, Wanninkhof R, Wong CS, Wallace DWR, Tilbrook B, Millero FJ, Peng T-U, Kozyr A, Ono T, Rios AF (2004) The oceanic sink for anthropogenic CO2. Science 305:367–371
Sampson RN, Apps MJ, Brown S, Cole CV, Downing J, Heath LS, Ojima DS, Smith TM, Solomon AM, Wisniewski J (1993) Workshop summary statement-terrestrial biospheric carbon fluxes-quantification of sinks and sources of CO2. Water Air Soil Pollut 70:3–15
Sedjo RA (1992) Temperate forest ecosystems in the global carbon cycle. AMBIO 21:274–277
Sindhoj E, Andren O, Katterer T, Gunnarsson S, Petersson R (2000) Projections of 30-year soil carbon balances for a semi-natural grassland under elevated CO2 based on measured root decomposability. Agric Ecosyst Env 114:360–368
Singh BR, Borresen T, Uhlen G, Ekeberg E (1998) Long-term effects of crop rotation, cultivation practices and fertilizers on carbon sequestration in soils in Norway. In: Lal R, Kimble JM, Follett RF, Stewart BA (eds) Management of carbon sequestration in soil. CRC Press, Boca Raton, pp 195–208
Singh BR, Lal R (2001) The potential of Norwegian soils to sequester carbon through land use conversion and improved management practices. The Ohio State University, Columbus, 69 pp
Smith P, Powlson DS (2000) Considering manure and carbon sequestration. Science 287:427–428
Smith P, Powlson DS, Glendining MJ, Smith JU (1997) Potential for carbon sequestration in European soils: preliminary estimates for five scenarios using results from long-term experiments. Glob Chang Biol 3:67–79
Smith P, Powlson DS, Glendining MJ, Smith JU (1998) Preliminary estimates of the potential for carbon mitigation in European soils through no-till farming. Glob Chang Biol 4:679–685
Smith P, Powlson DS, Smith JU, Falloon P, Coleman K (2000a) Meeting the U.K.’s climate change commitments: options for carbon mitigation on agricultural land. Soil Use Manage 16:1–11
Smith P, Powlson DS, Smith JU, Falloon P, Coleman K (2000b) Meeting Europe’s climate change commitments: quantitative estimates of the potential for carbon mitigation by agriculture. Glob Chang Biol 6:525–539
Smith P, Goulding KW, Smith KA, Powlson DS, Smith JU, Faloon P, Coleman K (2001) Enhancing the carbon sink in European agricultural soils: including trace gas fluxes in estimates of carbon mitigation potential. Nutr Cycl Agroecosyst 60:237–252
Smith P, Andren O, Karlsson T, Prala P, Regina K, Rounsevell M, van Wesemael B (2005) Carbon sequestration potential in European croplands has been overestimated. Glob Chang Biol 11:2153–2163
Sohlenius B, Boström S (1999) Effects of climate change on soil factors and metazoan microfauna (nematodes, tardigrades and rotifers) in a Swedish tundra soil – a soil transplantation experiment. Appl Soil Ecol 12:113–128
Turunen J, Moore TR (2003) Controls on carbon accumulation and storage in the mineral subsoil beneath peat in Lakkasuo mire, central Finland. Eur J Soil Sci 54:279–286
Uhlen G, Tveitnes S (1995) Effects of long-term crop rotation, fertilizers, farm manure and straw on soil productivity. Nor J Agric Sci 9:143–161
Van Dijk H (1982) Survey of Dutch soil organic research with regard to humification and degradation rates in arable land. In: Boels DD, Davis B, Johnston AE (eds) Land use seminar on land degradation. Balkema Rotterdam, pp 133–143
Vejre H, Callesen L, Vesterdal L, Raulun-Rasmussen K (2003) Carbon and nitrogen in Danish forest soils – contents and distribution determined by soil order. Soil Sci Soc Am J 67:335–343
Wessel WW, Tietema A, Beier C, Emmett BA, Penuelas J, Riis-Nielsen T (2004) A qualitative ecosystem assessment for different shrublands in western Europe under impact of climate change. Ecosystems 7:662–671
White A, Cannell MGR, Friend AD (1999) Climate change impacts on ecosystems and the terrestrial carbon sink: a new assessment. Glob Environ Change 9:S21–S30
WMO (2006) Greenhouse gas bulletin: the state of greenhouse gases in the atmosphere using global observations up to December 2004. WMO, Env Div, Geneva
Woods WI, Falcão NPS, Teixeira WG (2006) Biochar trials aim to enrich soil for smallholders. Nature 443:144
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Lal, R. Soil carbon stocks under present and future climate with specific reference to European ecoregions. Nutr Cycl Agroecosyst 81, 113–127 (2008). https://doi.org/10.1007/s10705-007-9147-x
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DOI: https://doi.org/10.1007/s10705-007-9147-x