• Title of article

    Predicting the rate and extent of cadmium and copper desorption from soils in the presence of bacterial extracellular polymer

  • Author/Authors

    Anna Jensen-Spaulding، نويسنده , , Kristen Cabral، نويسنده , , Michael L. Shuler، نويسنده , , Leonard W. Lion، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2004
  • Pages
    10
  • From page
    2231
  • To page
    2240
  • Abstract
    The movement of cationic transition metals through the subsurface is strongly retarded by sorption to the porous media. However, dissolved organic ligands can compete with soil surfaces by providing binding sites for metals in solution. An extracellular polymer produced by a bacterium isolated from soil was used in this study to observe and model the influence of a naturally occurring ligand on the release of adsorbed metals from two test soils. Experimental results show that the presence of dissolved extracellular polymer enhanced the rate and extent of desorptive release of soil-bound cadmium and copper. A kinetic model that uses a gamma distribution of rate constants to account for the physical and chemical heterogeneity of the soil matrix was employed to describe the release of cadmium and copper in batch experiments. Model parameters describing soil, metal and extracellular polymer interactions were obtained through separate experiments. With these parameters the model successfully predicted the influence of dissolved polymer on the rate and extent of release of cadmium and copper from soil in independent batch experiments. These results suggest that the presence of natural metal-binding ligands such as bacterial extracellular polymers can act to increase the driving force for desorption by lowering the aqueous concentration of free unbound metals in solution.
  • Keywords
    Bacteria , desorption kinetics , gamma distribution , Extracellular polymer , copper , lead
  • Journal title
    Water Research
  • Serial Year
    2004
  • Journal title
    Water Research
  • Record number

    769020