Zones of influence for soil organic matter dynamics A conceptual framework for data and models

Zones of influence for soil organic matter dynamics : A conceptual framework for data and models

© 2019 John Wiley & Sons Ltd.

Détails bibliographiques
Publié dans:Global change biology. - 1999. - 25(2019), 12 vom: 03. Dez., Seite 3996-4007
Auteur principal: Cagnarini, Claudia (Auteur)
Autres auteurs: Blyth, Eleanor, Emmett, Bridget A, Evans, Chris D, Griffiths, Robert I, Keith, Aidan, Jones, Laurence, Lebron, Inma, McNamara, Niall P, Puissant, Jeremy, Reinsch, Sabine, Robinson, David A, Rowe, Edwin C, Thomas, Amy R C, Smart, Simon M, Whitaker, Jeanette, Cosby, Bernard J
Format: Article en ligne
Langue:English
Publié: 2019
Accès à la collection:Global change biology
Sujets:Journal Article SOM model SOM persistence UNSDG-15 conceptual framework connectivity soil depth sustainable land management zones of influence Soil plus... Carbon 7440-44-0
Description
Résumé:© 2019 John Wiley & Sons Ltd.
Soil organic matter (SOM) is an indicator of sustainable land management as stated in the global indicator framework of the United Nations Sustainable Development Goals (SDG Indicator 15.3.1). Improved forecasting of future changes in SOM is needed to support the development of more sustainable land management under a changing climate. Current models fail to reproduce historical trends in SOM both within and during transition between ecosystems. More realistic spatio-temporal SOM dynamics require inclusion of the recent paradigm shift from SOM recalcitrance as an 'intrinsic property' to SOM persistence as an 'ecosystem interaction'. We present a soil profile, or pedon-explicit, ecosystem-scale framework for data and models of SOM distribution and dynamics which can better represent land use transitions. Ecosystem-scale drivers are integrated with pedon-scale processes in two zones of influence. In the upper vegetation zone, SOM is affected primarily by plant inputs (above- and belowground), climate, microbial activity and physical aggregation and is prone to destabilization. In the lower mineral matrix zone, SOM inputs from the vegetation zone are controlled primarily by mineral phase and chemical interactions, resulting in more favourable conditions for SOM persistence. Vegetation zone boundary conditions vary spatially at landscape scales (vegetation cover) and temporally at decadal scales (climate). Mineral matrix zone boundary conditions vary spatially at landscape scales (geology, topography) but change only slowly. The thicknesses of the two zones and their transport connectivity are dynamic and affected by plant cover, land use practices, climate and feedbacks from current SOM stock in each layer. Using this framework, we identify several areas where greater knowledge is needed to advance the emerging paradigm of SOM dynamics-improved representation of plant-derived carbon inputs, contributions of soil biota to SOM storage and effect of dynamic soil structure on SOM storage-and how this can be combined with robust and efficient soil monitoring
Description:Date Completed 28.11.2019
Date Revised 08.01.2020
published: Print-Electronic
Citation Status MEDLINE
ISSN:1365-2486
DOI:10.1111/gcb.14787