An investigation of the combined stable isotopic composition of methane emissions from northern wetlands
Methane is a radiatively active, naturally occurring atmospheric trace gas which is thought to account for as much as 19% of the enhanced greenhouse effect. Ice core studies have shown that the atmospheric concentration has more than doubled since pre-industrial times. Wetlands are the largest natur...
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| Format: | Thesis |
| Language: | unknown |
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1999
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| Online Access: | https://oro.open.ac.uk/54555/ https://oro.open.ac.uk/54555/1/264860.pdf https://doi.org/10.21954/ou.ro.0000d51b |
| Summary: | Methane is a radiatively active, naturally occurring atmospheric trace gas which is thought to account for as much as 19% of the enhanced greenhouse effect. Ice core studies have shown that the atmospheric concentration has more than doubled since pre-industrial times. Wetlands are the largest natural source of atmospheric methane, contributing around 21 % of the annual global flux. The magnitude of various sources of methane is still poorly defined. Stable isotope measurements are increasingly being used to constrain global budgets of atmospheric trace gases because isotopic analysis provides a much clearer picture of global atmospheric chemistry than CH 4 concentration measurements alone. Conventional analytical techniques for studying dual stable isotopic composition of methane (δ 13 C and δD) require prohibitively large quantities of CH 4 for analysis. At the Planetary Sciences Research Institute of the Open University, a highly sensitive static mass spectrometer has been developed which uniquely uses CH 4 as the analyte. The method requires only 8 ng of CH 4 for analysis «10 ml ambient air), making replicated measurements of the isotopic composition of CH 4 emissions from wetlands feasible for the first time. Methane emissions from an ombrotrophic mire in Snowdonia have been measured over 2 years, (1995-1997) and analysed for δ 17 M. Parallel laboratory studies have also been conducted, to constrain the effects of environmental variables such as peat temperature and water table depth. The presence of vascular plants enhanced methane flux. In the field, methane flux showed seasonal variation. Peat temperature and water table depth could account for 68% of this variation. The isotopic composition of methane flux from the ombrotrophic mire also exhibited seasonal variation, with δ 17 M ranging from -34 to -17‰. The lowest values were observed in summer and the highest in winter. Variations in the isotopic composition of peat water are unlikely to account for more than a 2‰ shift in δ 17 M. Although there was a ... |
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