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Land use change and soil organic carbon dynamics

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Abstract

Historically, soils have lost 40–90 Pg carbon (C) globally through cultivation and disturbance with current rates of C loss due to land use change of about 1.6 ± 0.8 Pg C y−1, mainly in the tropics. Since soils contain more than twice the C found in the atmosphere, loss of C from soils can have a significant effect of atmospheric CO2 concentration, and thereby on climate. Halting land-use conversion would be an effective mechanism to reduce soil C losses, but with a growing population and changing dietary preferences in the developing world, more land is likely to be required for agriculture. Maximizing the productivity of existing agricultural land and applying best management practices to that land would slow the loss of, or is some cases restore, soil C. There are, however, many barriers to implementing best management practices, the most significant of which in developing countries are driven by poverty. Management practices that also improve food security and profitability are most likely to be adopted. Soil C management needs to considered within a broader framework of sustainable development. Policies to encourage fair trade, reduced subsidies for agriculture in developed countries and less onerous interest on loans and foreign debt would encourage sustainable development, which in turn would encourage the adoption of successful soil C management in developing countries. If soil management is to be used to help address the problem of global warming, priority needs to be given to implementing such policies.

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Acknowledgements

The structure of this paper is based on a chapter prepared of a UN book “Impact of land use change on Soil Resources” (eds: AK Braimoh and PLG Vlek) but includes updated material arising from the IPCC WGIII (2007) report and other papers and reports published during 2006 and 2007. Gert-Jan Narbuurs and Eveline Trines provided interesting discussions regarding barriers to implementations of C sequestration and other land-based mitigation measures, which helped greatly in writing the section on overcoming barriers.

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  1. School of Biological Sciences, University of Aberdeen, Cruickshank Building, St Machar Drive, Aberdeen, AB24 3UU, UK

    Pete Smith

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Smith, P. Land use change and soil organic carbon dynamics. Nutr Cycl Agroecosyst 81, 169–178 (2008). https://doi.org/10.1007/s10705-007-9138-y

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