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Research Article
Natural variability in N export from headwater catchments: snow cover controls on ecosystem N retention
Article first published online: 5 OCT 1999
DOI: 10.1002/(SICI)1099-1085(199910)13:14/15<2191::AID-HYP849>3.0.CO;2-L
Copyright © 1999 John Wiley & Sons, Ltd.
Issue
1099-1085/asset/cover.gif?v=1&s=76d4ef1a9cca2fed0ae2507c6de984a0c96ede1d "Hydrological Processes")
Hydrological Processes
Special Issue: Snow Hydrology
Volume 13, Issue 14-15, pages 2191–2201, October 1999
Additional Information
How to Cite
Brooks, P. D., Campbell, D. H., Tonnessen, K. A. and Heuer, K. (1999), Natural variability in N export from headwater catchments: snow cover controls on ecosystem N retention. Hydrological Processes, 13: 2191–2201. doi: 10.1002/(SICI)1099-1085(199910)13:14/15<2191::AID-HYP849>3.0.CO;2-L
Publication History
- Issue published online: 5 OCT 1999
- Article first published online: 5 OCT 1999
- Manuscript Accepted: 11 MAR 1999
- Manuscript Revised: 11 DEC 1998
- Manuscript Received: 30 APR 1998
Funded by
- National Park Service. Grant Number: NASA/EOS (NAGW-2606)
- Niwot Ridge Long-Term Ecological Research Project. Grant Number: NSF DEB 9211776
- USGS Water Energy and Biogeochemical Budgets
- Loch Vale Watershed Long-term Ecological Research and Monitoring Program
- Abstract
- References
- Cited By
Keywords:
- snowmelt;
- nitrogen cycling;
- nitrogen saturation;
- snow cover;
- headwater catchments;
- catchment biogeochemistry
Abstract
The causes of natural variability in catchment scale N export need to be understood and quantified before the effects of increased N deposition in high elevation catchments can be evaluated. This study evaluates controls on the size of the leachable soil N pool concurrent with the spring hydrologic flush that is primarily responsible for the transport of N to surface water. In high elevation catchments in the western United States, sources of N during this snowmelt flush include both atmospheric N deposition stored in the snowpack until melt and mobile soil N pools, and sinks are dominated by biogeochemical processes that occur in soil under snow cover. Because soil processes may serve either as a source or sink for N, controls on the amount of inorganic N leached from soil during the snowmelt period were evaluated in the major landscape types in four catchments in Colorado. Measurements of leached N were inversely related to measurements of over-winter CO2 flux at all sites, indicating that N was immobilized in soil heterotrophic biomass. Because over-winter soil heterotrophic activity is controlled primarily by the depth and timing of snow accumulation, the importance of these plot scale measurements to catchment scale N export were evaluated using a long-term record of winter precipitation, N deposition, and N export from Loch Vale in Rocky Mountain National Park. This data set identified a strong, linear relationship (r2=0·68) between catchment scale N retention and winter snow cover, consistent with subnivean, soil based controls on the mobile N pool identified at the plot scale. These results indicate that the winter snow pack is the major control both on hydrologic N export and on soil source/sink relationships for N concurrent with this transport mechanism. The effect of winter snow cover on the fate of both atmospheric and soil N needs to be considered when evaluating potential the effects of increased N deposition on either terrestrial or aquatic ecosystems in seasonally snow-covered watersheds. In these systems, changes in surface water chemistry are likely to occur in high deposition, snow-covered sites during low snow years before terrestrial vegetation is affected. Copyright © 1999 John Wiley & Sons, Ltd.