Abstract
Soil solution chemistry was investigated at a forested watershed draining into Woods Lake. N.Y. as part of the Experimental Watershed Liming Study (EWLS). The objective of this study was to assess the response of soil water to watershed treatment of calcite (CaCO3). This material was applied in an effort to mitigate the effects of acidic atmospheric deposition. Soil solutions draining Oa and Bs horizons in reference subcatchments were characterized by low pH and acid neutralizing capacity (ANC) due to elevated concentrations of SO 2−4 , NO −3 and organic anions relative to the sum of base cation (CB Ca2+, Mg2+, Na+, K+) concentrations. Seasonal and spatial variation of pH andANC in soil solutions appeared to belargely controlled by variations in the concentrations of dissolved organic acids which, in turn, were regulated by reactions of Al with soil organic matter. Nitrate was positively correlated and SO2+ was negatively correlated with Ca2+ and Al concentrations in reference soil solutions, indicating that changes in NO −3 influences spatial and seasonal variations in Ca2+ and Al concentrations. On this basis, NO −3 appears to be important in soil acidification and the dynamics of drainage water acidity. Comparison of our results with historical data for the site showed declines in concentrations of SO 2−4 , which are consistent with decreases in emissions of SO4, in the eastern U.S. and atmospheric deposition of SO 2−4 , to the Adirondack region. Mineral soil solutions have shown large increases in concentrations of NO −3 . Declines in concentrations of CB and increases in concentrations of Al have occurred over the last ten years, suggesting depletion of soil pools of exchangeable basic cations and increased sensitivity to acidic deposition. Calcite (CaCO3) treatment of 6.89 Mg/ha resulted in a significant increase of Ca2+, ANC and pH in both Oa and Bs horizon soil solutions. Soil water response to CaCO3 addition was most evident during the first year after treatment, apparently due to macropore transport of particulate and dissolved CaCO3 However, increases in ANC and pH in the mineral soil waters were not sustained and appeared insufficient to result in substantial improvement in surface water quality over the 43 month study period.
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Geary, R.J., Driscoll, C.T. Forest soil solutions: Acid/base chemistry and response to calcite treatment. Biogeochemistry 32, 195–220 (1996). https://doi.org/10.1007/BF02187139
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DOI: https://doi.org/10.1007/BF02187139