arctic flux study: a regional view of trace gas release

Fluxes of trace gases from northern ecosystems represent a highly uncertain and potentially significant component of the arctic land-atmosphere system, especially in the context of greenhouse-induced climate change. The initial goal of the Arctic Flux Study (a part of NSF's Arctic System Scienc...

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Bibliographic Details
Published in:Journal of biogeography 1995-03, Vol.22 (2/3), p.365-374
Main Authors: Weller, G, Chapin, F.S, Everett, K.R, Hobbie, J.E, Kane, D, Oechel, W.C, Ping, C.L, Reeburgh, W.S, Walker, D, Walsh, J
Format: Article
Language:English
Subjects:
Atmospheric models
Carbon dioxide
Climate change
Climate models
Ecosystem models
Ecosystem Physiology
ecosystems
gas exchange
global warming
Hydrological modeling
Marine ecosystems
methane
Soil water
Terrestrial ecosystems
tundra
Vegetation
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Summary:Fluxes of trace gases from northern ecosystems represent a highly uncertain and potentially significant component of the arctic land-atmosphere system, especially in the context of greenhouse-induced climate change. The initial goal of the Arctic Flux Study (a part of NSF's Arctic System Science Program) is a regional estimate of the present and future movement of materials between the land, atmosphere and ocean in the Kuparuk River basin in northern Alaska. We are measuring rates and controls of processes along a north-south transect running from the marshy coastal plain to mountain valleys. Important vertical fluxes under study are the release of CO2and CH4from soils and water, lateral fluxes are surface water, nutrients, and organic matter. A hierarchy of measurements allow the rates and understanding of processes to be scaled from plots to the landscape, regional, and circumarctic level. These include gas flux measurements in small chambers, measurements over larger areas by eddy correlation from small towers, and measurements at the landscape scale from airplane overflights. Experimental manipulations of carbon dioxide, soil moisture, nutrients and soil temperature from this and other studies give information on process controls. The distribution of plant communities has been described at several landscape-scale sites and a hierarchic GIS has been developed for the region at three scales (plot, landscape, region). Climate is measured at six sites and hydrological processes are being studied at each watershed scale. In the soils, measurements are being made of soil organic matter and active layer thickness and of availability of soil organic matter for microbial transformation into CO2and CH4. Fluxes and process understanding have been incorporated into a hierarchy of models at different scales. These include models of regional climate nested in a GCM; of regional-and continental-scale plant productivity and carbon cycling incluing CO2release under altered climates; watershed and regional models of hydrology; and surface energy budgets. After the first year of study the regional climate model has been successfully configured to the northern Alaska region. We have also measured a large release of carbon dioxide from tundra soils in all but the coldest and wettest parts of the transect. The rates from eddy correlation towers (landscape level) agree closely with rates from chambers (plot level). Observations, experimental manipulations and modelling analy
ISSN:0305-0270
1365-2699
DOI:10.2307/2845932