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Tellus B: Chemical and Physical Meteorology Volume 48, 1996 - Issue 5
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Original Articles

Methane flux from northern wetlands and tundra

An ecosystem source modelling approach

T. R. ChristensenDepartment of Plant Ecology, Botanical Institute, Copenhagen, University @ster Farimagsgade 2D, DK-1353 Copenhagen K, Denmark. Email: [email protected]
,
I. C. PrenticeGlobal Systems Group, Department of Ecology, Lund University, Ecology Building, S-223 62Lund, Sweden;
,
J. KaplanGlobal Systems Group, Department of Ecology, Lund University, Ecology Building, S-223 62Lund, Sweden;
,
A. HaxeltineGlobal Systems Group, Department of Ecology, Lund University, Ecology Building, S-223 62Lund, Sweden;
&
S. SitchGlobal Systems Group, Department of Ecology, Lund University, Ecology Building, S-223 62Lund, Sweden;
Pages 652-661 | Received 11 Jan 1996, Accepted 11 Jun 1996, Published online: 18 Jan 2017

References

  • Aselmann, I. and Crutzen, P.J. 1989, Global distributions of natural freshwater wetlands and rice paddies, their net primary productivity, seasonality and possible methane emissions. Journal of Atmospheric Chemistry 8,307–358.
  • Bartlett, K.B., Crill, P., Sass, R.C., Harriss, R.S. and Dise, N.B. 1992. Methane emissions from tundra environments in the Yukon-Kuskokwim Delta, Alaska. Journal of Geophysical Research 97D, 16645–16660.
  • Bartlett, K.B. and Harriss, R.C. 1993. Review and assess-ment of methane emissions from wetlands, Chemosphere 26,261–320.
  • Botch, M.S., Kobak, K.I., Vinson, T.S. and Kolchugina, T.P. 1995. Carbon pools and accumulation in peat-lands of the former Soviet Union. Global Biogeochemical Cycles 9,37–46.
  • Bradbury IK. and Grace, J. 1983. Primary production in wetlands. In: Ecosystems of the world 4a, mires: swamp, bog, fen and moor, general studies (ed. Gore, A.J.P.) Elsevier, Oxford.
  • Bubier, J.L. and Moore, T.R. 1994. An ecological perspective on methane emissions from northern wetlands. Trends in Ecology and Evolution 9,460–464.
  • Cao, M., Marshall, S. and Gregson, K. 1996. Global carbon exchange and methane emissions from natural wetlands: Application of a process-based model. Journal of Geophysical Research, in press.
  • Chanton, J.P. and Whiting, G.J. 1995. Trace gas exchange in freshwater and coastal marine environments: ebulition and transport by plants. In: Biogenic trace gases: measuring emissions from soil and water (eds. Matson, PA. and Harriss, G.J.) Blackwell Science, London.
  • Christensen, T.R. 1993. Methane emission from Arctic tundra. Biogeochemistry 21,117–139.
  • Christensen, T.R. 1994. Exchange of radiatively active trace gases in tundra environments, with particular attention to methane, Ph.D. Thesis. University of Cambridge.
  • Christensen, T.R. and Cox, P. 1995a. Response of methane emission from arctic tundra to climatic change: results from a model simulation. Tellus 47B, 301–310.
  • Christensen, T.R. and Cox, P. 1995b. Modelling response of methane emission from arctic tundra to climatic change: an overview of relevant controlling factors. In: Global change and Arctic terrestrial ecosystems. Ecosystems research report 10 (ed. Callaghan, TN.). European Commission, Luxemburg, pp. 296–304.
  • Christensen, T.R., Jonasson, S., Callaghan, T.V. and Havström, M. 1995. Spatial variation in high latitude methane flux along a transect across Siberian and European tundra environments. Journal of Geophysical Research 100D, 21035–21045.
  • Clein, J.S. and Schimel, J.P. 1995. Microbial activity of tundra and taiga soils at sub-zero temperatures. Soil Biology and Biochemistry 27,1231–1234.
  • Clymo, R.S. and Reddaway E.J.F. 1971. Productivity of Sphagnum (bog-moss) and peat accumulation. Hidro-biologia 12,181–192.
  • Disc, N.B. 1992 Winter fluxes of methane from Minnesota peatlands. Biogeochemistry 17,71–83.
  • Dlugokencky, E.J., Masarie, K.A., Lang, P.M., Tans, P.P., Steele, L.P. and Nisbet, E.G. 1994. A dramatic decrease in the growth rate of atmospheric methane in the northern hemisphere during 1992. Geophysical Research Letters 19,2313–2316.
  • Fan, S.M., Wofsy S.C., Bakwin P.S., Jacob, D.J., Anderson, S.M., Kebabian, P.L., McManus, J.B., Kolb, C.E. and Fitzjarrald, D.R. 1992. Micrometeorological measurements of CH4 and CO2 exchange between the atmosphere and subarctic tundra. Journal of Geo-physical Research 97D, 16627–16644.
  • Fan, S.M., Goulden, M.L., Munger, J.W., Daube, B.C., Bakwin, P.S., Wofsy, S.C., Amthor, J.S., Fitzjarrald, D.R., Moore, K.E. and Moore, T.R. 1995. Environmental controls on the photosynthesis and respiration of a boreal lichen woodland: a growing season of whole-ecosystem exchange measurements by eddy correlation. Oecologia 102,443–452.
  • Frolking, S., and Crill, P. 1994. Climate controls on temporal variability of methane flux from a poor fen in southeastern New Hampshire: measurement and modeling. Global Biogeochemical Cycles 8,385–397.
  • Fung, I., John, J., Lerner, J., Matthews, E., Prather, M., Steele, L.P. and Fraser, P.J. 1991. Three-dimensional model synthesis of the Global methane cycle. Journal of Geophysical Research 96D, 13033–13065.
  • Gorham, E. 1991. Northern peatlands: role in the carbon cycle and probable responses to climatic warming. Ecological Applications 1, 182–195.
  • Haxeltine, A., Prentice, LC. and CressweU, I.D. 1996. A coupled carbon and water flux model to predict vegetation structure. Journal of Vegetation Science, in press.
  • Haxeltine, A. and Prentice, LC. 1996. A general model for the light/use efficiency of primary production. Functional Ecology, in press.
  • Hogg, E.H. 1993. Decay potential of hummock and hollow Sphagnum peats at different depths in a Swedish raised bog. Oikos 66,269–278.
  • IPCC 1990. Climate change. The Intergovernmental Panel on Climate Change ( IPCC ) Scientific Assessment.Cambridge University Press, Cambridge.
  • IPCC 1992. Climate change 1992. The supplementary report to The IPCC Scientific Assessment. Cambridge University Press, Cambridge.
  • IPCC (Intergovernmental Panel on Climate Change) 1995. Climate Change 1994, Radiative forcing of climate change and an evaluation of the IPCC IS92 emission scenarios. Cambridge University Press, Cambridge.
  • Klinger, L.F., Zimmerman, P.R., Greenberg, J.P., Heidt, L.E. and Guenther, A.B. 1994. Carbon trace gas fluxes along a successional gradient in the Hudson Bay low-land. Journal of Geophysical Research 99D, 1469–1494.
  • Lieth, H. and Wittaker, R.H. 1975. Primary productivity of the biosphere. Springer, Berlin.
  • Lloyd, J. and Taylor, J.A. 1994. On the temperature dependency of soil respiration. Functional Ecology 8, 315–323.
  • Martikainen, P.J., Nykänen, H., Alm, J. and Silvola, J. 1995. Changes in fluxes of carbon dioxide, methane and nitrous oxide due to forest drainage of mire sites of different trophy. Plant and Soil 168-169, 571–577.
  • Matthews, E. and Fung, I. 1987. Methane emission from natural wetlands: global distribution, area, and envir-onmental characteristics of sources. Global Biogeo-chemical Cycles 1, 61–86.
  • Matthews, E. and Fung, I. 1992. Global data bases on distribution, characteristics and methane emission of natural wetlands. Digital raster data on a 1-degree geographic (lat/long) 180 x 360 grid. In: Global ecosystems database version 1.0: Disc A. NOAA National Geophysical Data Center, Boulder.
  • Mcguire, A.D., Melillo, J.M., Toyle, L.A., Kicklighter, D.W., Grace, A.L., Moore III, B. and Vorosmarty, C.J. 1992. Interactions between carbon and nitrogen dynamics in estimating net primary productivity for potential vegetation in North America. Global Biogeo-chemical Cycles 6, 101–124.
  • Moore, T.R., Roulet, N. and Knowles, R. 1990. Spatial and temporal variations of methane flux from subarctic/northern boreal fens. Global Biogeochemical Cycles 4, 29–46.
  • Moore, T.R., Heyes, A. and Roulet, N.T. 1994. Methane emissions from wetlands, southern Hudson Bay low-land. Journal of Geophysical Research 99D, 1455–1467.
  • Morrissey, L.A. and Livingston, G.P. 1992. Methane Emission from Alaska Arctic Tundra: An Assessment of Local Spatial Variability. Journal of Geophysical Research 97D, 16661–16670.
  • Morrissey, L.A., Zobel, D.B. and Livingston, G.P. 1993. Significance of stomatal controls on methane release from Carex-dominated wetlands. Chemosphere 26, 339–355.
  • Nilsson, M. and Bohlin, E. 1993. Methane and carbon dioxide concentrations in bogs and fens-with special reference to the effects of the botanical composition of the peat. Journal of Ecology 81, 615–625.
  • Nykänen, H., Alm, J., Lang, K., Silvola, J. and Martikainen, P.J. 1995. Emission of CH4, N20 and CO2 from a virgin fen and a fen drained for grassland in Finland. Journal of Biogeography 22, 1149–1155.
  • Oechel, W.C., Hastings, S.T., Vourlitis, G., Jenkins, M., Riechers, G. and Grulke, N. 1993. Recent change of Arctic tundra ecosystems from a net carbon dioxide sink to a source. Nature 361, 520–523.
  • Ovenden, L. 1990. Peat accumulation in northern wetlands. Quaternary Research 33,377–386.
  • Panikov, N.S., Sizova, M.V., Zelenev, V.V., Machov, G.A., Naumov, A.V. and Gadzhiev, I.M. 1995. Methane and carbon dioxide emission from several vasyugan wetlands: spatial and temporal flux variations. Ecological Chemistry 4, 13–23.
  • Potter, C.S., Randerson, J.T., Field, C.B., Matson, P.A., Vitousek, P.M., Mooney, H.A. and Kloster, S.A. 1993. Terrestrial ecosystem production: a process model based on global satellite and surface data. Global Bio-geochemical Cycles 7, 811–841.
  • Prentice, I.C., Sykes, ST. and Cramer, W. 1993. A simulation model for the transient effects of climate change on forest landscapes. Ecological Modelling 65, 51–70.
  • Raich, J.W., Rastetter, E.B., Melillo, J.M., Kicklighter, D.W., Steudler, P.A., Peterson, B.J., Grace, A.L., Moore III, B. and Vorosmarty, C.J. 1991. Potential net primary productivity in South America: applica-tion of a global model. Ecological Applications 1, 399–429.
  • Reeburgh, W.S., Roulet, N.T. and Svensson, B. 1994. Terrestrial biosphere-atmosphere exchange in high latitudes. In: Global atmospheric-biospheric chemistry (ed. R.G. Prinn). Plenum Press, New York.
  • Roulet, N.T., Jano, A., Kelly, C.A., Klinger, L., Moore, T.R., Protz, R., Ritter, J.A. and Rouse, W.R. 1994. Role of the Hudson Bay lowland as a source of atmo-spheric methane. Journal of Geophysical Research 99D, 1439–1454.
  • Schimel, J.P. 1995. Plant transport and methane production as controls on methane flux from arctic wet meadow tundra. Biogeochemistry 28, 183–200.
  • Schtitz, H., Holzapfel-Pschorn, A., Conrad, R., Rennenberg, H. and Seiler, W. 1989. A 3-year continous record on the influence of daytime, season, and fertilizer treatment on methane emission rates from an Italian rice paddy. Journal of Geophysical Research 94D, 16405–16416.
  • Sebacher, Harriss, R.C., Bartlett, K.B., Sebacher, S.M. and Grice, S.S. 1986. Atmospheric methane sources: Alaskan tundra bogs, an alpine fen, and a subarctic boreal marsh. Tellus 38B, 1–10.
  • Shaver, G.R. and Chapin, F.S. 1991. Production: biomass relationships and element cycling in contrasting Arctic vegetation types. Ecological Monographs 61, 1–31.
  • Svensson, B.H. 1980. Carbon dioxide and methane fluxes from the ombrotrophic parts of a subarctic mire, In: Ecology of a subarctic mire. (ed. M. Sonesson), Swedish Natural Science Research Council, Stockholm.
  • Svensson, B.H. and Roswall, T. 1984. In situ methane production from acid peat in plant communities with different moisture regimes in a subarctic mire. Oikos 43, 341–50.
  • Svensson, B.H. and Sundh, I. 1992. Factors affecting methane production in peat soils. Suo, 43, 183–190.
  • Taylor, J.A., Brasseur, G.P., Zimmerman, P.R. and Cicerone, R.J. 1991. A study of the sources and sinks of methane and methyl chloroform using a global three-dimensional langrangian tropospheric tracer transport model. Journal of Geophysical Research 96D, 3013–3044.
  • Valentine, D.W., Holland, E.A. and Schimel, D.S. 1994. Ecosystem and physiological controls over methane production in northern wetlands. Journal of Geophysical Research 99D, 1563–1571.
  • VEMAP members, 1995. Vegetation/ecosystem modelling and analysis project: comparing biogeography and biogeochemistry models in a continental-scale study of terrestrial ecosystem responses to climate change and CO2 doubling. Global Biogeochemical Cycles 9, 407–437.
  • Wahlen, M. 1993. The global methane cycle. Annual Review of Earth and Planetary Science 21, 407–426.
  • Whalen, S.C. and Reeburgh, W.S. 1990. A methane flux transect along the Trans-Alaska Pipeline Haul Road. Tellus 42B, 237–249.
  • Whalen, S.C. and Reeburgh, W.S. 1992. Interannual vari-ations in tundra methane emissions: A four-year time-series at fixed sites. Global Biogeochemical Cycles 6, 139–159.
  • Whiting, G.J. and Chanton, J.P. 1992, Plant-dependent CH4 emission in a subarctic Canadian fen. Global Biogeochemical Cycles 6, 225–231.
  • Whiting, G.J. and Chanton, J.P. 1993. Primary production control of methane emission from wetlands. Nature 364, 794–795.
  • Whiting, G.J., Bartlett, D.S., Fan, S., Bakwin, P.S. and Wofsy, S.C. 1992. Biosphere/atmosphere CO2 exchange in tundra ecosystems: community character-istics and relationships with multispectral surface reflectance. Journal of Geophysical Research 97D, 16,671-16,680.
  • Whiting, G.J. 1994. CO2 exchange in the Hudson Bay lowlands: community characteristics and multispectral reflectance properties. Journal of Geophysical Research 99D, 1519–1528.
  • Zimov, S.A., Zimova, G.M., Daviodov, S.P., Daviodova, Al., Voropaev, Y.V., Voropaeva, Z.V., Prosiannikov, S.F. and Prosiannikova, O.V. 1993. Winter biotic activity and production of CO2 in siberian soils: a factor in the greenhouse effect. Journal of Geophysical Research 98D, 5017–5023.

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