Thomas G. Hinton,^*,† Daniel I. Kaplan,^‡ Anna S. Knox,^‡ Daniel P. Coughlin,^†
Rebecca V. Nascimento,^† Siobahn I. Watson,^† Dean E. Fletcher,^† and Bon-Jun Koo^†

University of Georgia, Savannah River Ecology Laboratory, Aiken, South Carolina 29802,
and Savannah River National Laboratory, Aiken, South Carolina 29802

 

Abstract
We hypothesized that adding micaceous minerals to ¹³⁷Cs-contaminated aquatic systems would serve as an effective in situ remediation technique by sequestering the contaminant and reducing its bioavailability. Results from several laboratory studies are presented from which an effective amendment material was chosen for a replicated field study. The field study was conducted over a 2-year period and incorporated 16 3.3-m diameter column-plots (limnocorrals) that were randomly placed in a ¹³⁷Cs-contaminated pond. The limnocorrals received three rates of amendment treatments to their water surfaces. The amendment material was a commercially available mineral with high sorption (K_d > 9000 L kg^-1) and low desorption (<20%) characteristics for cesium, even in the presence of high concentrations of the competing cation, NH₄⁺. In the treated limnocorrals, ¹³⁷Cs concentrations were reduced some 25-30-fold in the water, 4-5-fold in aquatic plants, and 2-3-fold in fish. The addition of the amendment did not adversely affect water chemistry, although increased turbidity and subsequent siltation did alter the aquatic macroinvertebrate insect community. This in situ technology provides a valuable, less-environmentally intrusive alternative to costly ex situ technologies that require the contaminated sediment to be excavated prior to treatment, or excavated and disposed of elsewhere.

*Corresponding author
Phone: (803)725-7454;
Fax: (803)725-7314;
E -mail: thinton@srel.edu.

† University of Georgia.
‡ Savannah River National Laboratory.

SREL Reprint #2975