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Regional Environmental Change

, Volume 7, Issue 2, pp 105–119 | Cite as

Changes in mineral soil organic carbon stocks in the croplands of European Russia and the Ukraine, 1990–2070; comparison of three models and implications for climate mitigation

  • P. SmithEmail author
  • J. U. Smith
  • U. Franko
  • K. Kuka
  • V. A. Romanenkov
  • L. K. Shevtsova
  • M. Wattenbach
  • P. Gottschalk
  • O. D. Sirotenko
  • D. I. Rukhovich
  • P. V. Koroleva
  • I. A. Romanenko
  • N. V. Lisovoi
Original Article

Abstract

Three soil carbon models (RothC, CANDY and the Model of Humus Balance) were used to estimate the impacts of climate change on agricultural mineral soil carbon stocks in European Russia and the Ukraine using detailed spatial data on land-use, future land-use, cropping patterns, agricultural management, climate and soil type. Scenarios of climate were derived from the Hadley Centre climate Version 3 (HadCM3) model; future yields were determined using the Soil–Climate–Yield model, and land use was determined from regional agricultural and economic data and a model of agricultural economics. The models suggest that optimal management, which entails the replacement of row crops with other crops, and the use of extra years of grass in the rotation could reduce Soil organic carbon (SOC) loss in the croplands of European Russia and the Ukraine by 30–44% compared to the business-as-usual management. The environmentally sustainable management scenario (SUS), though applied for a limited area within the total region, suggests that much of this optimisation could be realised without damaging profitability for farmers.

Keywords

Soil carbon Model Sustainability Climate change Impact RothC CANDY Model of humus balance 

Abbreviations

BAU

Business-as-usual management scenario

OPT

Optimal economic management scenario

SUS

Environmentally sustainable management scenario

HadCM3

Hadley centre climate model Version 3

SOC

Soil organic carbon

UNFCCC

United Nations framework convention on climate change

RothC

Rothamsted carbon model

GIS

Geographical information system

IPCC

Intergovernmental panel on climate change

SRES

Special report on emissions scenarios

PET

Potential evapotranspiration

RAPS

Regional agricultural production systems

FYM

Farm yard manure

N

Nitrogen

C

Carbon

IOM

Inert organic matter

BCP

Bioclimatic potential

Notes

Acknowledgements

This work was funded by INTAS project MASC-FSU (INTAS-2001-0116/F5).

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Copyright information

© Springer-Verlag 2007

Authors and Affiliations

  • P. Smith
    • 1
    Email author
  • J. U. Smith
    • 1
  • U. Franko
    • 2
  • K. Kuka
    • 2
  • V. A. Romanenkov
    • 3
  • L. K. Shevtsova
    • 3
  • M. Wattenbach
    • 1
  • P. Gottschalk
    • 1
  • O. D. Sirotenko
    • 4
  • D. I. Rukhovich
    • 5
  • P. V. Koroleva
    • 5
  • I. A. Romanenko
    • 6
  • N. V. Lisovoi
    • 7
  1. 1.School of Biological SciencesUniversity of AberdeenAberdeenUK
  2. 2.Department of Soil PhysicsHelmholtz Centre for Environmental Research—UFZHalleGermany
  3. 3.Pryanishnikov All-Russian Institute of Agrochemistry (VNIIA)MoscowRussia
  4. 4.All-Russian Institute of Agricultural MeteorologyObninsk, Kaluga RegionRussia
  5. 5.Dokuchaev Soil Science InstituteMoscowRussia
  6. 6.All-Russian Institute of Agricultural Problems and InformaticsMoscowRussia
  7. 7.Institute for Soil Science and Agrochemistry Research named after O.N. SokolovskyKharkiv-24Ukraine

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