The Potential Impact of Agricultural Management and Climate Change on Soil Organic Carbon of the North Central Region of the United States
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Andren O, Katterer T. 2001. The ICBM family of analytically solved models of soil carbon, nitrogen and microbial biomass dynamics—descriptions and application examples. Ecol Mod 136:191–207
Batjes NH. 2002. Revised soil parameter estimates for the soil types of the world. Soil Use Man 18:232–5
Buyanovsky GA, Wagner GH. 1998. Carbon cycling in cultivated land and its global significance. Glob Chan Biol 4:131–41
Coleman K, Jenkinson DS. 1990. RothC 26.3-A model for the turnover of carbon in soil. In: Powlson DS, Smith P, Smith JU, Eds. Evaluation of soil organic matter models using long-term datasets, NATO ASI Series I, Vol. 38. Berlin Heidelberg New York: Springer
Cure JD, Acock B. 1986. Crop responses to carbon dioxide doubling: a literature survey. Agric For Meteorol 38:127–45
Donigan AS Jr, Barnwell TO, Jackson RB, Patwardhan AS, Weinrich KB, Rowell AL, Chinnaswamy RV, Cole CV. 1994. Assessment of alternative management practices and policies affecting soil carbon in agroecosystems of the central United States. Publication No. EPA/600/R-94/067. Athens (GA): U.S. Environmental Protection Agency
Evrendilek F, Wali MK. 2001. Modelling long-term C dynamics in croplands in the context of climate change: a case study from Ohio. Environ Model Softw 16(4):361–75
Franzmeier DP, Lemme GD, Miles RJ. 1985. Organic carbon in soils of the North Central United States. Soil Sci Soc Am J 49:702–8
Gage S, Colunga-Garcia M, Helly JJ, Safir GR, Momin A. 2001. Structural design for management and visualization of information for simulation models applied to a regional scale. Comput Electron Agric 33:77–84
Grace PR, Ladd JN. 1995. SOCRATES (Soil Organic Carbon Reserves And Transformations in Agro-Ecosystems): a decision support system for sustainable farming systems in southern Australia. Adelaide (SA): Cooperative Research Centre for Soil and Land Management.
Grace PR, Ladd JN, Robertson GP, Gage SH. 2006. SOCRATES—a simple model for predicting long-term changes in soil organic carbon in terrestrial ecosystems. Soil Biol Biochem (in press)
Izaurralde RC, Haugen-Korzyra KL, Jans DC, McGill WB, Grant RF, Hiley JC. 2001. Soil C dynamics: measurement, simulation and site-to-region scale-up. In: Lal R, Kimble JM, Follett RF, Stewart BA, Eds. Assessment methods of soil carbon. Boca Raton (FL): CRC Press. p 553–75
Jackson RB, Canadell J, Erlinger JR, Mooney HA, Dala OE, Schulze ED. 1996. A global analysis of root distributions for terrestrial biomes. Oecolog 108:389–411
Jenkinson DS. 1990. The turnover of organic carbon and nitrogen in soil. Philos Trans R Soc Lond B 329:361–8
Jenkinson DS, Adams DE, Wild A. 1991. Model estimates of CO2 emissions from soil in response to global warming. Nature 351:304–6
Kern JS. 1994. Spatial patterns of soil organic carbon in the contiguous United States. Soil Sci Soc Am J 58:439–55
Kern JS. 1995. Geographic patterns of soil water-holding capacity in the contiguous United States. Soil Sci Soc Am J 59:1126–33
King AW, Post WM, Wullschleger SD. 1997. The potential response of terrestrial carbon storage to changes in climate and atmospheric CO2. Clim Change 35:199–227
Kuchler AW. 1964. Potential natural vegetation of the conterminous United States. In: American geographical society special publication 36. New York: American Geographical Society
Lal R, Kimble JM, Follett RF, Cole CV. 1998. The potential of U.S. cropland to sequester carbon and mitigate the greenhouse effect. Ann Arbor (MI): Sleeping Bear Press
Ladd JN, Amato M, Grace PR, van Veen JA. 1995. Simulation of 14C turnover through the microbial biomass in soils incubated with 14C-labelled plant residues. Soil Biol Biochem 27:777–83
Lieth H. 1975. Modeling the primary productivity of the world. In: Lieth H, Whittaker RH, Eds. Primary productivity of the biosphere. Berlin Hedelberg New York: Springer. p 237–63
Marland G, Boden TA, Andres RJ. 2003. Global, regional, and national CO2 emissions. In: Trends: a compendium of data on global change. Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory. Oak Ridge (TN): U.S. Department of Energy
McCarl BA, Schneider UA. 2000. U.S. Agriculture’s role in a greenhouse gas emission mitigation world: an economic perspective. Rev Agric Econ 22:134–59
Parton WJ, Rasmussen PE. 1994. Long term effects in crop management-fallow: II. Century model formulation. Soil Sci Soc Am J 58:530–6
Pittock AB, Nix HA. 1986. The effect of changing climate on Australian biomass production—a preliminary study. Clim Change 8:243–55
Polglase PJ, Wang YP. 1992. Potential CO2-enhanced carbon storage by the terrestrial biosphere. Aust J Bot 40:641–56
Post WM, Peng TH, Emanuel WR, King AW, Dale VH, DeAngelis DL. 1990. The global carbon cycle. Am Sci 78:310–26
Prince SD, Haskett J, Steininger M, Strand H, Wright R. 2001. Net primary production of U.S. Midwest croplands from agricultural harvest yield data. Ecol App 11:1194–205
Ramankutty N, Foley JA. 1999. Estimating historical changes in land cover: North American croplands from 1850 to 1992. Global Ecol Biogeogr 8:381–96
Skjemstad JO, Janik LJ. 1996. Climate change: determining the potential for carbon sequestration in Australian soils. Final Report to the Rural Industries R & D Corporation. CSO-5A, Canberra
USDA. 1994. State soil geographic (STATSGO) data base. NRCS. Miscellaneous Publication 1492, 113 p
USDA. 1982. Soil geography—NATSGO map series, national resource inventory
VEMAP Members. 1995. Vegetation/Ecosystem Modeling and Analysis Project (VEMAP): comparing biogeography and biogeochemistry models in a continental-scale study of terrestrial ecosystem responses to climate change and CO2 doubling. Glob Biogeochem Cycles 9:407–37
Vogelmann JE, Howard SM, Yang L, Larson CR, Wylie BK, Van Driel N. 2001. Completion of the 1990s national land cover data set for the conterminous United States from landsat thematic mapper data and ancillary data sources, photogram. Eng Rem Sens 67:650–2