R. P. Hooper
Peter S. Murdoch
Thomas G. Huntington
1996
<p>Biogeochemical studies in small watersheds provide an analytical approach to understand how ecosystems respond to natural climatic variations and human-induced environmental change. Small watersheds, usually less than 5 km2, are small enough to permit characterization and understanding of ecosystem processes within relatively simple, homogeneous biological and physical settings; yet they are large enough to incorporate more complex processes and element cycles than can be studied at plot scales. Watersheds comprise discrete hydrochemical environments allowing quantification of hydrologic, element, and energy budgets. Element budgets, or mass balances, can be quantified as the difference between the mass of a solute that enters a watershed in wet and dry deposition and leaves a watershed in streamflow. Element budgets are primary tools used to investigate biogeochemical processes. Monitoring various aspects of element budgets to assess ecosystem health and stability is analogous to measuring the pulse or blood chemistry of a patient. Monitoring streamwater chemistry, basic climate, soil, and biotic variables provide a means to integrate complex biogeochemical processes and evaluate trends in water quality. Small watershed studies provide a scientific basis to develop predictive models of watershed function.</p><p><br>Major emphases of small watershed studies include investigation of hydrologic and chemical responses to natural climate variation, anthropogenic stressors, and alternate forest-management practices. The nature and significance of biogeochemical research in small watersheds is reviewed by Moldan and Cerny (1994). The U.S. Geological Survey, U.S. Department of Agriculture Forest Service, and other federal agencies support several long-term small watershed studies to provide insight into a variety of ecosystem processes. Long-term records are essential to distinguish trends resulting from natural climatic variations or other stressors. The following sites, with noted periods of records, are examples of intensively studied forested watersheds in eastern USA supported by federal agencies:<br>■ Coweeta Hydrologic Laboratory, North Carolina, (1939-present), Swank and Crossley (1988).<br>■ Hubbard Brook Experimental Forest, New Hampshire, (1956-present), Bormann and Likens (1979).<br>■ Sleepers River Research Watershed, Vermont, (1958-present), Shanley et al. (1995).<br>■ Walker Branch Watershed, Tennessee, (1967-present), Johnson and Van Hook (1989).<br>■ Catoctin Mountains Research Site, Maryland, (1982-present), Rice and Bricker (1995).<br>■ Catskill Stream Network, New York, (1983- present), Murdoch and Stoddard (1992).<br>■ Panola Mountain Research Watershed, Georgia, (1985-present), Huntington et al. (1993).</p><p><br>Small watershed studies also provide essential baseline information for understanding variations in water quality and element cycling in "pristine" ecosystems that can be used as benchmarks to evaluate anthropogenic impacts and alternate watershed management practices. This paper provides examples of how analytical tools developed through watershed research provide insight into ecosystem processes and can contribute to the management of watershed resources. </p>
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Small watershed studies: Analytical approaches for understanding ecosystem response to environmental change
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