| Literature DB >> 20573048 |
W I J Dieleman1, S Luyssaert, A Rey, P de Angelis, C V M Barton, M S J Broadmeadow, S B Broadmeadow, K S Chigwerewe, M Crookshanks, E Dufrêne, P G Jarvis, A Kasurinen, S Kellomäki, V Le Dantec, M Liberloo, M Marek, B Medlyn, R Pokorný, G Scarascia-Mugnozza, V M Temperton, D Tingey, O Urban, R Ceulemans, I A Janssens.
Abstract
Under elevated atmospheric CO(2) concentrations, soil carbon (C) inputs are typically enhanced, suggesting larger soil C sequestration potential. However, soil C losses also increase and progressive nitrogen (N) limitation to plant growth may reduce the CO(2) effect on soil C inputs with time. We compiled a data set from 131 manipulation experiments, and used meta-analysis to test the hypotheses that: (1) elevated atmospheric CO(2) stimulates soil C inputs more than C losses, resulting in increasing soil C stocks; and (2) that these responses are modulated by N. Our results confirm that elevated CO(2) induces a C allocation shift towards below-ground biomass compartments. However, the increased soil C inputs were offset by increased heterotrophic respiration (Rh), such that soil C content was not affected by elevated CO(2). Soil N concentration strongly interacted with CO(2) fumigation: the effect of elevated CO(2) on fine root biomass and -production and on microbial activity increased with increasing soil N concentration, while the effect on soil C content decreased with increasing soil N concentration. These results suggest that both plant growth and microbial activity responses to elevated CO(2) are modulated by N availability, and that it is essential to account for soil N concentration in C cycling analyses.Entities:
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Year: 2010 PMID: 20573048 DOI: 10.1111/j.1365-3040.2010.02201.x
Source DB: PubMed Journal: Plant Cell Environ ISSN: 0140-7791 Impact factor: 7.228