Simulated mechanisms of soil N feedback on the forest CO2 response
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Author list: Pepper DA, Eliasson PE, McMurtrie RE, Corbeels M, Agren GI, Stromgren M, Linder S
Publisher: Wiley: 12 months
Place: OXFORD
Publication year: 2007
Journal: Global Change Biology (1354-1013)
Journal acronym: GLOBAL CHANGE BIOL
Volume number: 13
Issue number: 6
Start page: 1265
End page: 1281
Number of pages: 17
ISSN: 1354-1013
eISSN: 1365-2486
Languages: English-Great Britain (EN-GB)
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Abstract
An improved understanding of the response of forest ecosystems to elevated levels of CO2 in the atmosphere is crucial because atmospheric CO2 concentration continues to increase at an accelerating rate and forests are an important sink in the global carbon cycle. Several CO2-enrichment experiments have now been running for more than 10 years, with highly variable short-term results after the first decade. Responses to rising [CO2] over the next few decades will depend on several plant and ecosystem feedbacks that are inadequately understood. In this study, we conduct a sensitivity analysis, within the context of the simulated CO2 response, using a new version of the G'DAY ecosystem model, with an improved decomposition submodel, applied to a nitrogen-limited Norway spruce forest site in the north of Sweden. The new decomposition model incorporates important modifications to soil processes, including some that constitute negative feedbacks on an ecosystem's growth response to elevated [CO2]. The sensitivity analysis reveals key parameters and processes that are important for the simulated CO2 response on the short term and others that are more important on the long term. A process that has a strong impact on the short-term response is a change in decomposer composition, potentially in response to altered litter quality. Parameters that become increasingly important in the long term are carbon allocation to root exudates that are directly or indirectly associated with atmospheric N-2 fixation, and the rate of humification of soil organic matter. We identify factors intrinsic to species and site (microbes and resources) and ecosystem nutrient supply that determine the duration of the enhanced simulated growth response to elevated [CO2].
Keywords
CO2 fertilization, ecosystem, forest, modelling, net primary production, Nitrogen, soil processes
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