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Invited Review

Soil organic matter turnover is governed by accessibility not recalcitrance

  1. Jennifer A. J. Dungait1,*,
  2. David W. Hopkins1,2,†,
  3. Andrew S. Gregory3,
  4. Andrew P. Whitmore3

Article first published online: 13 MAR 2012

DOI: 10.1111/j.1365-2486.2012.02665.x

Issue

Global Change Biology

Global Change Biology

Volume 18, Issue 6, pages 1781–1796, June 2012

Additional Information

How to Cite

Dungait, J. A. J., Hopkins, D. W., Gregory, A. S. and Whitmore, A. P. (2012), Soil organic matter turnover is governed by accessibility not recalcitrance. Global Change Biology, 18: 1781–1796. doi: 10.1111/j.1365-2486.2012.02665.x

Author Information

  1. 1

    Department of Sustainable Soils and Grassland Systems, Rothamsted Research, North Wyke, Okehampton, Devon, UK

  2. 2

    School of Life Sciences, Heriot-Watt University, Edinburgh, UK

  3. 3

    Department of Sustainable Soils and Grassland Systems, Rothamsted Research, Harpenden, Herts, UK

  1. Rothamsted Honorary Fellow

*Correspondence: Dr Jennifer A. J. Dungait, tel. + 44 0 1837 883 500; fax + 44 0 1837 82 139, e-mail: jennifer.dungait@rothamsted.ac.uk

  1. Rothamsted Honorary Fellow

Publication History

  1. Issue published online: 8 MAY 2012
  2. Article first published online: 13 MAR 2012
  3. Accepted manuscript online: 14 FEB 2012 10:51AM EST
  4. Manuscript Accepted: 3 FEB 2012
  5. Manuscript Received: 1 FEB 2012
  6. Manuscript Revised: 1 FEB 2012

Funded by

  • NERC. Grant Numbers: NE/D00893X1, NE/H022503/1

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Keywords:

  • C isotopes;
  • decomposition;
  • recalcitrance;
  • soil C models;
  • soil microorganisms;
  • soil organic matter

Abstract

Mechanisms to mitigate global climate change by sequestering carbon (C) in different ‘sinks' have been proposed as at least temporary measures. Of the major global C pools, terrestrial ecosystems hold the potential to capture and store substantially increased volumes of C in soil organic matter (SOM) through changes in management that are also of benefit to the multitude of ecosystem services that soils provide. This potential can only be realized by determining the amount of SOM stored in soils now, with subsequent quantification of how this is affected by management strategies intended to increase SOM concentrations, and used in soil C models for the prediction of the roles of soils in future climate change. An apparently obvious method to increase C stocks in soils is to augment the soil C pools with the longest mean residence times (MRT). Computer simulation models of soil C dynamics, e.g. RothC and Century, partition these refractory constituents into slow and passive pools with MRTs of centuries to millennia. This partitioning is assumed to reflect: (i) the average biomolecular properties of SOM in the pools with reference to their source in plant litter, (ii) the accessibility of the SOM to decomposer organisms or catalytic enzymes, or (iii) constraints imposed on decomposition by environmental conditions, including soil moisture and temperature. However, contemporary analytical approaches suggest that the chemical composition of these pools is not necessarily predictable because, despite considerable progress with understanding decomposition processes and the role of decomposer organisms, along with refinements in simulation models, little progress has been made in reconciling biochemical properties with the kinetically defined pools. In this review, we will explore how advances in quantitative analytical techniques have redefined the new understanding of SOM dynamics and how this is affecting the development and application of new modelling approaches to soil C.

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