Grassland Management Influences the Response of Soil Respiration to Drought

Grassland Management Influences the Response of Soil Respiration to Drought

Increasing soil carbon stocks in agricultural grasslands has a strong potential to mitigate climate change. However, large uncertainties around the drivers of soil respiration hinder our ability to identify management practices that enhance soil carbon sequestration. In a context where more intense...

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Bibliographic Details
Published in:Agronomy (Basel) Vol. 9; no. 3; p. 124
Main Authors: Moinet, Gabriel, Midwood, Andrew, Hunt, John, Rumpel, Cornelia, Millard, Peter, Chabbi, Abad
Format: Journal Article
Language:English
Published: Basel MDPI AG 2019
MDPI
Subjects:
Agricultural practices
Carbon
Carbon dioxide
Carbon sequestration
Climate change
Climate change mitigation
Dairy cattle
Dairy farming
Dairy farms
Drought
Experiments
Farm management
grassland
Grassland management
Grasslands
Life Sciences
management practices
Moisture content
Mowing
Nitrogen
Precipitation
Rain
Respiration
Rhizosphere
soil respiration
soil volumetric water content
Soil water
stable carbon isotopes
Water content
France
Europe
soil respiration
soil volumetric water content
stable carbon isotopes
management practices
grassland
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Summary:Increasing soil carbon stocks in agricultural grasslands has a strong potential to mitigate climate change. However, large uncertainties around the drivers of soil respiration hinder our ability to identify management practices that enhance soil carbon sequestration. In a context where more intense and prolonged droughts are predicted in many regions, it is critical to understand how different management practices will temper drought-induced carbon losses through soil respiration. In this study, we compared the impact of changing soil volumetric water content during a drought on soil respiration in permanent grasslands managed either as grazed by dairy cows or as a mowing regime. Across treatments, root biomass explained 43% of the variability in soil respiration (p < 0.0001). Moreover, analysis of the isotopic composition of CO2 emitted from the soil, roots, and root-free soil suggested that the autotrophic component largely dominated soil respiration. Soil respiration was positively correlated with soil water content (p = 0.03) only for the grazed treatment. Our results suggest that the effect of soil water content on soil respiration was attributable mainly to an effect on root and rhizosphere activity in the grazed treatment. We conclude that farm management practices can alter the relationship between soil respiration and soil water content.
ISSN:2073-4395
2073-4395
DOI:10.3390/agronomy9030124