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Methane (CH4) emission from a tidal marsh in the Min River estuary, southeast China
The total methane emission to the atmosphere and hydrosphere, and its seasonal variation, were estimated using an enclosed static chamber technique from a tidal marshes dominated by Phragmites australis (common reed) in the Min River estuary, southeast China. Measurements were taken at three tidal stages (before flood, during the flooding and ebbing process, and after ebb). Potential rates of methane production from the marsh sediment layers were also measured using an incubation technique. This P. australis tidal marsh was a net methane source, emitting 32.59 and 6.87 g CH4· m-2· yr-1 to the atmosphere and hydrosphere, respectively. There was considerable monthly variation with emissions greater before flood in some months, whereas at other months emission was greater after ebb. The average methane fluxes were 5.13, 5.06 and 4.74 mg CH4 m-2 h-1 before flood, during flooding and ebbing, and after ebb, respectively. Emissions to the tidewater and the atmosphere during the flooding and ebbing process were 2.98 and 2.08 mg CH4 m-2 h-1,respectively. Sediment methane production potential (0-40 cm depth) ranged from 0.028-0.123 μ g CH4· g-1· d-1, with the greatest production was in the surface soil. Methane fluxes had a significant correlation with atmospheric, sediment temperature and above ground biomass. The implications of these data for global warming are discussed briefly.
Methane (CH4) emission from a tidal marsh in the Min River estuary, southeast China
The total methane emission to the atmosphere and hydrosphere, and its seasonal variation, were estimated using an enclosed static chamber technique from a tidal marshes dominated by Phragmites australis (common reed) in the Min River estuary, southeast China. Measurements were taken at three tidal stages (before flood, during the flooding and ebbing process, and after ebb). Potential rates of methane production from the marsh sediment layers were also measured using an incubation technique. This P. australis tidal marsh was a net methane source, emitting 32.59 and 6.87 g CH4· m-2· yr-1 to the atmosphere and hydrosphere, respectively. There was considerable monthly variation with emissions greater before flood in some months, whereas at other months emission was greater after ebb. The average methane fluxes were 5.13, 5.06 and 4.74 mg CH4 m-2 h-1 before flood, during flooding and ebbing, and after ebb, respectively. Emissions to the tidewater and the atmosphere during the flooding and ebbing process were 2.98 and 2.08 mg CH4 m-2 h-1,respectively. Sediment methane production potential (0-40 cm depth) ranged from 0.028-0.123 μ g CH4· g-1· d-1, with the greatest production was in the surface soil. Methane fluxes had a significant correlation with atmospheric, sediment temperature and above ground biomass. The implications of these data for global warming are discussed briefly.
Methane (CH4) emission from a tidal marsh in the Min River estuary, southeast China
Tong, Chuan (author) / Wang, Wei-Qi (author) / Zeng, Cong-Sheng (author) / Marrs, Rob (author)
Journal of Environmental Science and Health, Part A ; 45 ; 506-516
2010-03-01
11 pages
Article (Journal)
Electronic Resource
English
Methane (CH4) emission from a tidal marsh in the Min River estuary, southeast China
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