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Atmospheric sulfur deposition alters pathways of gaseous carbon production in peatlands
Author(s) -
Vile Melanie A.,
Bridgham Scott D.,
Wieder R. Kelman,
Novák Martin
Publication year - 2003
Publication title -
global biogeochemical cycles
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.512
H-Index - 187
eISSN - 1944-9224
pISSN - 0886-6236
DOI - 10.1029/2002gb001966
Subject(s) - methanogenesis , peat , sulfate , mineralization (soil science) , environmental chemistry , environmental science , sulfur , sink (geography) , deposition (geology) , chemistry , methane , ecology , geology , soil science , soil water , sediment , biology , paleontology , cartography , organic chemistry , geography
Peatlands represent large carbon (C) reservoirs that can act as a source or sink for greenhouse gases. The response of peatland gaseous C fluxes to global climate change and atmospheric sulfate deposition, however, remains uncertain. Methanogenesis is thought to be one of the most important anaerobic C mineralization pathways in peatlands, especially in regions where input of sulfate from acid deposition is low. However, sulfate reduction has been quantified rarely in freshwater wetlands. Here we report greater anaerobic C flow through sulfate reduction than through methanogenesis at all sites situated along a global atmospheric sulfur deposition gradient. Stoichiometric mass balance suggests that fermentation is a dominant anaerobic C mineralization pathway in unpolluted peatlands, while methanogenesis contributed minimally to total anaerobic carbon mineralization in these sites. Furthermore, global increases of atmospheric sulfur deposition minimize the impacts of climatic warming by simultaneously decreasing rates of methanogenesis while causing little change in rates of total anaerobic C mineralization in Sphagnum ‐dominated peatlands.