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No overall stimulation of soil respiration under mature deciduous forest trees after 7 years of CO2 enrichment
JournalArticle (Originalarbeit in einer wissenschaftlichen Zeitschrift)
 
ID 462219
Author(s) Bader, Martin K. -F.; Koerner, Christian
Author(s) at UniBasel Körner, Christian
Year 2010
Title No overall stimulation of soil respiration under mature deciduous forest trees after 7 years of CO2 enrichment
Journal Global change biology
Volume 16
Number 10
Pages / Article-Number 2830-2843
Keywords carbon cycle, elevated CO2, FACE, fine root respiration, soil CO2 efflux
Abstract The anthropogenic rise in atmospheric CO2 is expected to impact carbon (C) fluxes not only at ecosystem level but also at the global scale by altering C cycle processes in soils. At the Swiss Canopy Crane (SCC), we examined how 7 years of free air CO2 enrichment (FACE) affected soil CO2 dynamics in a ca. 100-year-old mixed deciduous forest. The use of 13C-depleted CO2 for canopy enrichment allowed us to trace the flow of recently fixed C. In the 7th year of growth at similar to 550 ppm CO2, soil respiratory CO2 consisted of 39% labelled C. During the growing season, soil air CO2 concentration was significantly enhanced under CO2-exposed trees. However, elevated CO2 failed to stimulate cumulative soil respiration (R-s) over the growing season. We found periodic reductions as well as increases in instantaneous rates of R-s in response to elevated CO2, depending on soil temperature and soil volumetric water content (VWC; significant three-way interaction). During wet periods, soil water savings under CO2-enriched trees led to excessive VWC (> 45%) that suppressed R-s. Elevated CO2 stimulated R-s only when VWC was < 40% and concurrent soil temperature was high (> 15 degrees C). Seasonal Q(10) estimates of R-s were significantly lower under elevated (Q(10)=3.30) compared with ambient CO2 (Q(10)=3.97). However, this effect disappeared when three consecutive sampling dates of extremely high VWC were disregarded. This suggests that elevated CO2 affected Q(10) mainly indirectly through changes in VWC. Fine root respiration did not differ significantly between treatments but soil microbial biomass (C-mic) increased by 14% under elevated CO2 (marginally significant). Our findings do not indicate enhanced soil C emissions in such stands under future atmospheric CO2. It remains to be shown whether C losses via leaching of dissolved organic or inorganic C (DOC, DIC) help to balance the C budget in this forest.
Publisher Blackwell Science
ISSN/ISBN 1354-1013
edoc-URL http://edoc.unibas.ch/dok/A5841550
Full Text on edoc No
Digital Object Identifier DOI 10.1111/j.1365-2486.2010.02159.x
ISI-Number WOS:000281676700016
Document type (ISI) Article
 
   

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