Global effects of plant litter alterations on soil CO2 to the atmosphere

Soil respiration (Rs) is the largest terrestrial carbon (C) efflux to the atmosphere and is predicted to increase drastically through global warming. However, the responses of Rs to global warming are complicated by the fact that terrestrial plant growth and the subsequent input of plant litter to s...

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Bibliographic Details
Published in:Global change biology 2018-08, Vol.24 (8), p.3462-3471
Main Authors: Chen, Xinli, Chen, Han Y. H.
Format: Article
Language:English
Subjects:
aridity index
Atmosphere
Carbon dioxide
Climate change
double litter
Duration
Ecosystem assessment
Ecosystems
Efflux
Environmental changes
experimental duration
Global warming
Litter
Litter fall
Litter removal
Plant growth
Priming
priming effect
Q 10
Removal
root removal
Sensitivity
Sensitivity analysis
Soil
soil respiration
Soils
Substrates
Temperature
Terrestrial ecosystems
Terrestrial environments
Water availability
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Summary:Soil respiration (Rs) is the largest terrestrial carbon (C) efflux to the atmosphere and is predicted to increase drastically through global warming. However, the responses of Rs to global warming are complicated by the fact that terrestrial plant growth and the subsequent input of plant litter to soil are also altered by ongoing climate change and human activities. Despite a number of experiments established in various ecosystems around the world, it remains a challenge to predict the magnitude and direction of changes in Rs and its temperature sensitivity (Q10) due to litter alteration. We present a meta‐analysis of 100 published studies to examine the responses of Rs and Q10 to manipulated aboveground and belowground litter alterations. We found that 100% aboveground litter addition (double litter) increased Rs by 26.1% (95% confident intervals, 18.4%–33.7%), whereas 100% aboveground litter removal, root removal and litter + root removal reduced Rs by 22.8% (18.5%–27.1%), 34.1% (27.2%–40.9%) and 43.4% (36.6%–50.2%) respectively. Moreover, the effects of aboveground double litter and litter removal on Rs increased with experimental duration, but not those of root removal. Aboveground litter removal marginally increased Q10 by 6.2% (0.2%–12.3%) because of the higher temperature sensitivity of stable C substrate than fresh litter. Estimated from the studies that simultaneously tested the responses of Rs to aboveground litter addition and removal and assuming negligible changes in root‐derived Rs, “priming effect” on average accounted for 7.3% (0.6%–14.0%) of Rs and increased over time. Across the global variation in terrestrial ecosystems, the effects of aboveground litter removal, root removal, litter + root removal on Rs as well as the positive effect of litter removal on Q10 increased with water availability. Our meta‐analysis indicates that priming effects should be considered in predicting Rs to climate change‐induced increases in litterfall. Our analysis also highlights the need to incorporate spatial climate gradient in projecting long‐term Rs responses to litter alterations. We present a meta‐analysis to examine the responses of Rs and Q10 to manipulated aboveground and belowground litter alterations and found that aboveground litter addition increased, whereas aboveground litter removal, root removal and litter + root removal reduced Rs respectively. Moreover, the effects of aboveground litter addition and litter removal on Rs increased with exper
ISSN:1354-1013
1365-2486
DOI:10.1111/gcb.14147