Abstract
Much of the biogeochemical cycling research in catchments in the past 25 years has been driven by acid deposition research funding. This research has focused on vulnerable base-poor systems; catchments on alkaline lithologies have received little attention. In regions of high acid loadings, however, even well-buffered catchments are susceptible to forest decline and episodes of low alkalinity in streamwater. As part of a collaboration between the Czech and U.S. Geological Surveys, we compared biogeochemical patterns in two well-studied, well-buffered catchments: Pluhuv Bor in the western Czech Republic, which has received high loading of atmospheric acidity, and Sleepers River Research Watershed in Vermont, U.S.A., where acid loading has been considerably less. Despite differences in lithology, wetness, forest type, and glacial history, the catchments displayed similar patterns of solute concentrations and flow. At both catchments, base cation and alkalinity diluted with increasing flow, whereas nitrate and dissolved organic carbon increased with increasing flow. Sulfate diluted with increasing flow at Sleepers River, while at Pluhuv Bor the sulfate-flow relation shifted from positive to negative as atmospheric sulfur (S) loadings decreased and soil S pools were depleted during the 1990s. At high flow, alkalinity decreased to near 100 μeq L-1 at Pluhuv Bor compared to 400 μeq L-1 at Sleepers River. Despite the large amounts of S flushed from Pluhuv Bor soils, these alkalinity declines were caused solely by dilution, which was greater at Pluhuv Bor relative to Sleepers River due to greater contributions from shallow flow paths at high flow. Although the historical high S loading at Pluhuv Bor has caused soil acidification and possible forest damage, it has had little effect on the acid/base status of streamwater in this well-buffered catchment.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Bailey, S.W., Mayer, B. and Mitchell, M. J.: ‘The influence of mineral weathering on drainage water sulfate in Vermont and New Hampshire’, Hydrological Processes(in press).
Czech Hydrometeorological Institute: 2001, Air pollution in the Czech Republic in 2000, Czech, Hydrometeorological Institute, Prague, Czech Republic, pp. 213.
David, M. B. and Lawrence, G. B.: 1996, ‘Soil and soil solution chemistry under red spruce stands across the northeastern U.S.A.’, Soil Sci. 161, 314-328.
Driscoll, C. T., Lawrence, G. B., Bulger, A. J., Butler, T. J., Cronan, C. S., Eagar, C., Lambert, K. F., Likens, G. E., Stoddard, J. L. and Weathers, K. C.: 2001, ‘Acidic deposition in the northeastern United States: Sources and inputs, ecosystem effects, and management strategies’, BioScience 51, 180-198.
Dunne, T. and Black, R. D.: 1970, ‘An experimental investigation of runoff production in permeable soils’, Water Resour. Res. 6, 478-490.
Fottová, D. and Skořepová, I.: 1998, ‘Changes inmass element fluxes and their importance for critical loads: GEOMON network, Czech Republic’, Water, Air, Soil Pollut. 105, 365-376.
Hruška, J., Moldan, F. and Krám, P.: 2002, ‘Recovery from acidification in central Europe - Observed and predicted changes of soil and streamwater chemistry in the Lysina catchment, Czech Republic’, Environ. Pollut. 120, 261-274.
Kopáček, J., Veselý, J. and Stuchlík, E.: 2001, ‘Sulphur and nitrogen fluxes and budgets in the Bohemian Forest and Tatra Mountains during the Industrial Revolution (1850-2000)’, Hydrol. Earth Sys. Sci. 5, 391-405.
Krám, P. and Hruška, J.: 1994, ‘Influence of bedrock geology on elemental fluxes in two forested catchments affected by high acidic deposition’, Appl. Hydrogeol. 2, 50-58.
Krám, P., Hruška, J., Wenner, B. S., Driscoll, C. T. and Johnson, C. E.: 1997, ‘The biogeochemistry of basic cations in two acid-impacted forest catchments with contrasting lithology’, Biogeochemistry 37, 173-202.
Lischeid, G., Böttcher, H., Krám, P. and Hruška, J.: 2002, ‘Comparative analysis of hydrochemical time series of adjacent catchments by process-based and data-oriented modelling’, in G. H. Schmitz (ed.), Water Resources and Environmental Research, Vol. 2, Matter and Particle Transport in Surface and Subsurface Flow, Technical University Dresden, Germany, pp. 237-241.
Novák, M., Bottrell, S. H., Fottová, D., Buzek, F., Groscheová, H. and Žák, K.: 1996, ‘Sulfur isotope signals in forest soils in Central Europe along an air pollution gradient’, Environ. Sci. Technol. 30, 3473-3476.
Roberts, B. A. and Proctor, J. (eds): 1992, The Ecology of Areas with Serpentinized Rocks: A World View, Geobotany 17, Kluwer Academic Publishers, Dordrecht, pp. 427.
Rochelle, B. P., Church, M. R., and David, M. B.: 1987, ‘Sulfur retention at intensively-studied watersheds in the U.S. and Canada’, Water, Air, Soil Pollut. 33, 73-83.
Shanley, J. B. and Chalmers, A. T.: 1999, ‘The effect of frozen soil on snowmelt runoff at Sleepers River, Vermont’, Hydrol. Process. 13, 1843-1857.
Shanley, J. B., Schuster, P. F., Reddy, M. M., Roth, D. A., Taylor, H. E. and Aiken, G. R.: 2002a, ‘Mercury on the move during snowmelt in Vermont’, EOS, Trans. Am. Geophys. Union 83, 45-48.
Shanley, J. B., Kendall, C., Smith, T. E., Wolock, D. M. and McDonnell, J. J.: 2002b, ‘Controls on old and new water contributions to streamflow in some nested catchments in Vermont, U.S.A.’, Hydrol. Process. 16, 589-609.
U.S. EPA: 2000, National Air Pollutant Emission Trends, 1900-1998, U.S. Environmental Protection Agency, EPA-454/R-00-002, pp. 238.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Shanley, J.B., Krám, P., Hruška, J. et al. A Biogeochemical Comparison of Two Well-Buffered Catchments with Contrasting Histories of Acid Deposition. Water, Air, & Soil Pollution: Focus 4, 325–342 (2004). https://doi.org/10.1023/B:WAFO.0000028363.48348.a4
Issue Date:
DOI: https://doi.org/10.1023/B:WAFO.0000028363.48348.a4