Meta-analysis of global soil data identifies robust indicators for short-term changes in soil organic carbon stock following land use change

Samuel Eze; Matthew Magilton; Daniel Magnone; Sandra Varga; Iain Gould; Theresa G Mercer; Matthew R Goddard

doi:10.1016/j.scitotenv.2022.160484

Meta-analysis of global soil data identifies robust indicators for short-term changes in soil organic carbon stock following land use change

Sci Total Environ. 2023 Feb 20:860:160484. doi: 10.1016/j.scitotenv.2022.160484. Epub 2022 Nov 25.

Authors

Samuel Eze¹, Matthew Magilton², Daniel Magnone³, Sandra Varga⁴, Iain Gould⁵, Theresa G Mercer³, Matthew R Goddard²

Affiliations

¹ Department of Life Sciences, School of Life and Environmental Sciences, University of Lincoln, LN6 7DL Lincoln, UK. Electronic address: seze@lincoln.ac.uk.
² Department of Life Sciences, School of Life and Environmental Sciences, University of Lincoln, LN6 7DL Lincoln, UK.
³ Department of Geography, School of Life and Environmental Sciences, University of Lincoln, LN6 7DL Lincoln, UK; Lincoln Centre for Ecological Justice, University of Lincoln, LN6 7DL Lincoln, UK.
⁴ Department of Life Sciences, School of Life and Environmental Sciences, University of Lincoln, LN6 7DL Lincoln, UK; Lincoln Centre for Ecological Justice, University of Lincoln, LN6 7DL Lincoln, UK.
⁵ Lincoln Institute for Agri-food Technology, University of Lincoln, LN6 7DL Lincoln, UK.

PMID: 36436632
DOI: 10.1016/j.scitotenv.2022.160484

Abstract

The restoration of degraded lands and minimizing the degradation of productive lands are at the forefront of many environmental land management schemes around the world. A key indicator of soil productivity is soil organic carbon (SOC), which influences the provision of most soil ecosystem services. A major challenge in direct measurement of changes in SOC stock is that it is difficult to detect within a short timeframe relevant to land managers. In this study, we sought to identify suitable early indicators of changes in SOC stock and their drivers. A meta-analytical approach was used to synthesize global data on the impacts of arable land conversion to other uses on total SOC stock, 12 different SOC fractions and three soil structural properties. The conversion of arable lands to forests and grasslands accounted for 91 % of the available land use change datasets used for the meta-analysis and were mostly from Asia and Europe. Land use change from arable lands led to 50 % (32-68 %) mean increase in both labile (microbial biomass C and particulate organic C - POC) and passive (microaggregate, 53-250 μm diameter; and small macroaggregate, 250-2000 μm diameter) SOC fractions as well as soil structural stability. There was also 37 % (24-50 %) mean increase in total SOC stock in the experimental fields where the various SOC fractions were measured. Only the POC and the organic carbon stored in small macroaggregates had strong correlation with total SOC: our findings reveal these two SOC fractions were predominantly controlled by biomass input to the soil rather than climatic factors and are thus suitable candidate indicators of short-term changes in total SOC stock. Further field studies are recommended to validate the predictive power of the equations we developed in this study and the use of the SOC metrics under different land use change scenarios.

Keywords: Carbon sequestration; Land use change; Soil aggregation; Soil degradation; Soil restoration.

Publication types

Meta-Analysis
Review

MeSH terms

Biomass
Carbon
Carbon Sequestration
Ecosystem*
Forests
Soil* / chemistry

Substances

Soil
Carbon