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Watershed- and plot-scale tests of the mobile anion concept

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Abstract

Anion fluxes from a forest soil are usually correlated with those of base cations (BC). Declines in base cation deposition or long-term depletion from the soil may change these relationships. We used multiple regression to identify biogeochemical variables predicting annual volume-weighted concentrations of BC in streamwater draining a forested watershed, and analysis of variance to compare the effects of Ca and Cl inputs on BC fluxes out of soil horizons in irrigated plots. For the watershed, anion concentrations in streamwater predicted BC export most precisely (R 2=0.84). The best two-variable model (adjustedR 2=0.91) also included BC concentration in bulk deposition. Consistent with predictions from equations governing exchange chemistry, the proportion of charge contributed by Ca2+ increased with increasing total anion concentration, while that of Na+ decreased. At the plot scale, Cl concentrations in treatment solutions had a stronger effect (p=0.06) on BC concentration in Oa-horizon solutions than did Ca2+ concentrations (p=0.33). In individual horizons of individual plots, BC and total ion concentrations were correlated, but cation composition was not consistent within horizons from different plots. This study detected no evidence of longterm cation depletion in the soils controlling streamwater, but did detect extremely base-poor plots. Because acid deposition affects surface horizons first, streamwater chemistry may not be an adequate way to assess nutrient supply of forest soils.

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Abbreviations

AD:

anion deficit

BC:

base cations

HBEF:

Hubbard Brook Experimental Forest

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Author notes

  1. Martin J. Christ

    Present address: Department of Biology, West Virginia University, 26506, Morgantown, WV, USA

Authors and Affiliations

  1. Department of Biological Sciences, Rutgers University, 08855, Piscataway, NJ, USA

    Martin J. Christ

  2. Department of Civil and Environmental Engineering, Syracuse University, 13244, Syracuse, NY, USA

    Charles T. Driscoll

  3. Institute of Ecosystem Studies, 12545, Millbrook, NY, USA

    Gene E. Likens

Authors
  1. Martin J. Christ
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  2. Charles T. Driscoll
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  3. Gene E. Likens
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Christ, M.J., Driscoll, C.T. & Likens, G.E. Watershed- and plot-scale tests of the mobile anion concept. Biogeochemistry 47, 335–353 (1999). https://doi.org/10.1007/BF00992913

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  • DOI: https://doi.org/10.1007/BF00992913

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