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Elevated CO₂ Stimulates Net Accumulations of Carbon and Nitrogen in Land Ecosystems: A Meta-Analysis
The capability of terrestrial ecosystems to sequester carbon (C) plays a critical role in regulating future climatic change yet depends on nitrogen (N) availability. To predict long-term ecosystem C storage, it is essential to examine whether soil N becomes progressively limiting as C and N are sequ...
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Published in: | Ecology (Durham) 2006-01, Vol.87 (1), p.53-63 |
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Main Authors: | , , |
Format: | Article |
Language: | English |
Subjects: | |
Online Access: | Get full text |
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Summary: | The capability of terrestrial ecosystems to sequester carbon (C) plays a critical role in regulating future climatic change yet depends on nitrogen (N) availability. To predict long-term ecosystem C storage, it is essential to examine whether soil N becomes progressively limiting as C and N are sequestered in long-lived plant biomass and soil organic matter. A critical parameter to indicate the long-term progressive N limitation (PNL) is net change in ecosystem N content in association with C accumulation in plant and soil pools under elevated CO₂. We compiled data from 104 published papers that study C and N dynamics at ambient and elevated CO₂. The compiled database contains C contents, N contents, and C:N ratio in various plant and soil pools, and root:shoot ratio. Averaged C and N pool sizes in plant and soil all significantly increase at elevated CO₂ in comparison to those at ambient CO₂, ranging from a 5% increase in shoot N content to a 32% increase in root C content. The C and N contents in litter pools are consistently higher in elevated than ambient CO₂ among all the surveyed studies whereas C and N contents in the other pools increase in some studies and decrease in other studies. The high variability in CO₂-induced changes in C and N pool sizes results from diverse responses of various C and N processes to elevated CO₂. Averaged C:N ratios are higher by 3% in litter and soil pools and 11% in root and shoot pools at elevated relative to ambient CO₂. Elevated CO₂ slightly increases root:shoot ratio. The net N accumulation in plant and soil pools at least helps prevent complete down-regulation of, and likely supports, long-term CO₂ stimulation of C sequestration. The concomitant C and N accumulations in response to rising atmospheric CO₂ may reflect intrinsic nature of ecosystem development as revealed before by studies of succession over hundreds to millions of years. |
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ISSN: | 0012-9658 1939-9170 |
DOI: | 10.1016/j.jconrel.2006.05.010 |