A synthesis of methane emissions from 71 northern,temperate, and subtropical wetlands |
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| Authors: | Merritt R. Turetsky Agnieszka Kotowska Jill Bubier Nancy B. Dise Patrick Crill Ed R. C. Hornibrook Kari Minkkinen Tim R. Moore Isla H. Myers‐Smith Hannu Nykänen David Olefeldt Janne Rinne Sanna Saarnio Narasinha Shurpali Eeva‐Stiina Tuittila J. Michael Waddington Jeffrey R. White Kimberly P. Wickland Martin Wilmking |
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| Affiliation: | 1. Department of Integrative Biology, University of Guelph, , Guelph, Ontario, Canada;2. Environmental Studies Department, Mount Holyoke College, , South Hadley, MA, 01075 USA;3. School of Science and the Environment, Manchester Metropolitan University, , Manchester, M15 6BH UK;4. Department of Geological Sciences, Stockholm University, , Stockholm, 106 91 Sweden;5. School of Earth Sciences, University of Bristol, Wills Memorial Building, , Bristol, BS8 1RJ UK;6. Department of Forest Sciences, University of Helsinki, , Helsinki, FI‐00014 Finland;7. Department of Geography and Global Environmental and Climate Change Centre, McGill University, , Montreal, Quebec, H3A 0B9 Canada;8. School of GeoSciences, University of Edinburgh, , Edinburgh, EH9 3JN UK;9. Department of Biological and Environmental Science, University of Jyv?skyl?, , Jyv?skyl?, FI‐40014 Finland;10. Department of Physics and the Department of Geosciences and Geography, University of Helsinki, , Helsinki, FI‐00014 Finland;11. Department of Biology, University of Eastern Finland and Finnish Environment Institute, The Joensuu Office, , Joensuu, 80101 Finland;12. Department of Environmental Science, University of Eastern Finland, , FI‐70211 Kuopio Finland;13. School of Forestry, University of Eastern Finland, , Joensuu, Finland;14. School of Geography & Earth Sciences, McMaster University, , Hamilton, Ontario, L8S4L Canada;15. School of Public and Environmental Affairs, Indiana University, , Bloomington, Indiana, 47405‐2204 USA;16. US Geological Survey, , Boulder, CO, 80303 USA;17. Institute of Botany and Landscape Ecology, University Greifswald, , Greifswald, D‐17487 Germany |
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| Abstract: | Wetlands are the largest natural source of atmospheric methane. Here, we assess controls on methane flux using a database of approximately 19 000 instantaneous measurements from 71 wetland sites located across subtropical, temperate, and northern high latitude regions. Our analyses confirm general controls on wetland methane emissions from soil temperature, water table, and vegetation, but also show that these relationships are modified depending on wetland type (bog, fen, or swamp), region (subarctic to temperate), and disturbance. Fen methane flux was more sensitive to vegetation and less sensitive to temperature than bog or swamp fluxes. The optimal water table for methane flux was consistently below the peat surface in bogs, close to the peat surface in poor fens, and above the peat surface in rich fens. However, the largest flux in bogs occurred when dry 30‐day averaged antecedent conditions were followed by wet conditions, while in fens and swamps, the largest flux occurred when both 30‐day averaged antecedent and current conditions were wet. Drained wetlands exhibited distinct characteristics, e.g. the absence of large flux following wet and warm conditions, suggesting that the same functional relationships between methane flux and environmental conditions cannot be used across pristine and disturbed wetlands. Together, our results suggest that water table and temperature are dominant controls on methane flux in pristine bogs and swamps, while other processes, such as vascular transport in pristine fens, have the potential to partially override the effect of these controls in other wetland types. Because wetland types vary in methane emissions and have distinct controls, these ecosystems need to be considered separately to yield reliable estimates of global wetland methane release. |
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| Keywords: | bog carbon disturbance fen graminoids peat swamp temperature vegetation water table |
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