My Account: Log In | Join | Renew
Search
Author
Title
Vol.
Issue
Year
1st Page

Abstract

 

This article in JEQ

  1. Vol. 29 No. 3, p. 855-865
     
    Received: Apr 13, 1999
    Published: May, 2000


    * Corresponding author(s): ulf.skyllberg@sek.slu.se
 View
 Download
 Alerts
 Permissions
 Share

doi:10.2134/jeq2000.00472425002900030022x

Binding of Mercury(II) to Reduced Sulfur in Soil Organic Matter along Upland-Peat Soil Transects

  1. Ulf Skyllberg *,
  2. Kang Xia,
  3. Paul R. Bloom,
  4. Edward A. Nater and
  5. William F. Bleam
  1. Dep. of Soil, Water and Climate, Univ. of Minnesota, 1991 Upper Buford Circle, St. Paul, MN 55108;
    Dep. of Agronomy, Kansas State Univ.;
    Soil Science Dep., Univ. of Wisconsin, Madison WI 53706.

Abstract

Abstract

The binding of Hg2+ in organic matter of soils and waters controls the transport and transformations of Hg in terrestrial and aquatic ecosystems. We developed a competitive complexation method using the strong complexation of Hg2+ by Br for determining the Hg2+ binding strength in organic soils at native and elevated Hg concentrations. The distribution coefficients determined in KBr suspensions for sorption of native Hg2+ to soil organic carbon (SOC) (KSOC) are in the range of 1022 to 1023. The KSOC significantly decreased with increased additions of Hg2+ and with decreasing pH. Using data for reduced organic S concentrations determined by x-ray absorption near-edge structure spectroscopy (XANES), we calculated surface complex formation constants on the order of 1032 for a model site having acidity constants of mercaptoacetic acid. This value is in fair agreement with the tabulated value of 10345 for Hg2+ binding in mercaptoacetic acid. At native Hg concentrations, formation constants and KSOC values were similar for different types of soil organic matter along transects from uplands into wetlands, despite varying concentrations of Hg and reduced organic S. Our adsorption data are consistent with the conclusions from our previous extended x-ray absorption fine structure spectroscopy (EXAFS) study that in a humic acid and soil, Hg2+ ions bond in two-fold coordination involving one reduced S and one O or N.

  Please view the pdf by using the Full Text (PDF) link under 'View' to the left.

Copyright © .