%0 Journal Article %1 1992TellB..44..100R %A Roulet, N. %A Moore, T. %A Bubier, J. %A Lafleur, P. %D 1992 %J Tellus Series B Chemical and Physical Meteorology B %K CO2 atmospheric_methane carbon_dioxide climate_change fen methane peat peatlands %P 100-105 %T Northern fens - Methane flux and climatic change %V 44 %X Methane flux from northern peatlands is believed to be an important contribution to the global methane budget. High latitude regions are predicted to experience significant changes in surface temperature and precipitation associated with the 2 x CO2 climate scenarios, but the effects of these changes on methane emission are poorly understood. A peatland hydrologic model predicted June-August decreases in water storage of between 82 and 144 mm, using as inputs increases in temperatures of 3 C and rainfall of 1 mm/d. These changes translate into a water table drop, relative to the peat surface, of between 14 and 22 cm, depending on whether the fen has a floating or nonfloating surface. The 3 C air temperature increase was predicted to raise peat temperature at 10 cm depth by 0.8 C. These changes were then applied to relationships derived at a subarctic fen for water table: methane flux: temperature at 10 cm depth. Increased temperatures raise the methane flux by between 5 and 40 percent, but the lowered water table decreases methane flux by 74 and 81 percent, at the floating and nonfloating fen sites, respectively. These results suggest that methane emissions from northern peatlands are more sensitive to changes in moisture regime than temperature within the range of changes predicted for 2 x CO2 scenarios.

@article{1992TellB..44..100R, abstract = {Methane flux from northern peatlands is believed to be an important contribution to the global methane budget. High latitude regions are predicted to experience significant changes in surface temperature and precipitation associated with the 2 x CO2 climate scenarios, but the effects of these changes on methane emission are poorly understood. A peatland hydrologic model predicted June-August decreases in water storage of between 82 and 144 mm, using as inputs increases in temperatures of 3 C and rainfall of 1 mm/d. These changes translate into a water table drop, relative to the peat surface, of between 14 and 22 cm, depending on whether the fen has a floating or nonfloating surface. The 3 C air temperature increase was predicted to raise peat temperature at 10 cm depth by 0.8 C. These changes were then applied to relationships derived at a subarctic fen for water table: methane flux: temperature at 10 cm depth. Increased temperatures raise the methane flux by between 5 and 40 percent, but the lowered water table decreases methane flux by 74 and 81 percent, at the floating and nonfloating fen sites, respectively. These results suggest that methane emissions from northern peatlands are more sensitive to changes in moisture regime than temperature within the range of changes predicted for 2 x CO2 scenarios.}, added-at = {2008-05-14T03:08:28.000+0200}, adsnote = {Provided by the SAO/NASA Astrophysics Data System}, adsurl = {http://adsabs.harvard.edu/abs/1992TellB..44..100R}, author = {{Roulet}, N. and {Moore}, T. and {Bubier}, J. and {Lafleur}, P.}, biburl = {https://www.bibsonomy.org/bibtex/2d0ff98a898d8b082b4147b1871544556/thulefoth}, description = {Northern fens - Methane flux and climatic change}, interhash = {0d94e4fb25761ba6d71615821a806cba}, intrahash = {d0ff98a898d8b082b4147b1871544556}, journal = {Tellus Series B Chemical and Physical Meteorology B}, keywords = {CO2 atmospheric_methane carbon_dioxide climate_change fen methane peat peatlands}, month = {April}, pages = {100-105}, timestamp = {2008-05-14T03:08:28.000+0200}, title = {{Northern fens - Methane flux and climatic change}}, volume = 44, year = 1992 }