A new estimate of global soil respiration from 1970 to 2008

Soil respiration (Rs) is one of the key processes that underline our understanding of carbon cycle in terrestrial ecosystems. Great uncertainty remains in the previous global Rs estimates with a difference of 70 Pg C a-l between the highest and lowest estimates. Thus, the present study aimed to esti...

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Bibliographic Details
Published in:Chinese science bulletin 2013-11, Vol.58 (33), p.4153-4160
Main Authors: Chen, ShuTao, Huang, Yao, Xie, Wei, Zou, JianWen, Lu, YanYu, Hu, ZhengHua
Format: Article
Language:English
Subjects:
air temperature
carbon sequestration
Chemistry/Food Science
climatic factors
data collection
Earth Sciences
Engineering
Humanities and Social Sciences
Life Sciences
Monte Carlo method
multidisciplinary
Physics
Science
Science (multidisciplinary)
soil properties
soil respiration
terrestrial ecosystems
topsoil
tropical forests
uncertainty
估计
土壤呼吸
年际变化
气候因素
温度距平
蒙特卡罗方法
资源丰富
陆地生态系统
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Summary:Soil respiration (Rs) is one of the key processes that underline our understanding of carbon cycle in terrestrial ecosystems. Great uncertainty remains in the previous global Rs estimates with a difference of 70 Pg C a-l between the highest and lowest estimates. Thus, the present study aimed to estimate the global annual Rs and investigate the interannual and spatial variability in global an- nual Rs using a semi-mechanistic, empirically-based model which included climatic factors (temperature and precipitation) and topsoil (0-20 cm) organic carbon storage. About 657 published studies of annual Rs from 147 measurement sites were included in this meta-analysis. The global data sets from 1970 to 2008 on climate, surface air temperature, and soil properties were collected. The Monte Carlo method was used to propagate the simulation errors to global Rs~. The results indicated that the mean annual global Rs was 94.4 Pg C a-I, increasing at roughly 0.04 Pg C a-1 (-0.04% a-1) from 1970 to 2008. The Rs rate increased from colder, drier and less soil carbon-rich regions to warmer, moister and more carbon-rich regions. Highest Rs rates appeared in the tropical forest, while the lowest ones were in polar and desert regions. The annual Rs correlated directly with global temperature anomalies, suggesting that the interannual variability in temperature was responsible for the interannual variations in predicted global Rs. The global Rs increased from high-latitude zones to low-latitude zones. Further studies are recommended to explore the relationship between soil respiration and vegetation characters.
ISSN:1001-6538
1861-9541
DOI:10.1007/s11434-013-5912-1