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- Title
Biogeochemical and plant trait mechanisms drive enhanced methane emissions in response to whole-ecosystem warming.
- Authors
Noyce, Genevieve L.; Megonigal, J. Patrick
- Abstract
Climate warming perturbs ecosystem carbon (C) cycling, causing both positive and negative feedbacks on greenhouse gas emissions. In 2016, we began a tidal marsh field experiment in two vegetation communities to investigate the mechanisms by which whole-ecosystem warming alters C gain, via plant-driven sequestration in soils, and C loss, primarily via methane (CH4) emissions. Here, we report the results from the first four years. As expected, warming of 5.1 °C more than doubled CH4 emissions in both plant communities. We propose this was caused by a combination of four mechanisms: (i) a decrease in the proportion of CH4 consumed by CH4 oxidation, (ii) more C substrates available for methanogenesis, (iii) reduced competition between methanogens and sulfate reducing bacteria, and (iv) indirect effects of plant traits. Plots dominated by Spartina patens consistently emitted more CH4 than plots dominated by Schoenoplectus americanus, indicating key differences in the roles these common wetland plants play in affecting anerobic soil biogeochemistry and suggesting that plant composition can modulate coastal wetland responses to climate change.
- Subjects
WETLAND soils; SULFATE-reducing bacteria; COASTAL wetlands; TUNDRAS; WETLAND plants; METHANE; CHEMICAL composition of plants; SALT marsh ecology
- Publication
Biogeosciences Discussions, 2020, p1
- ISSN
1810-6277
- Publication type
Article
- DOI
10.5194/bg-2020-376