Adsorption and Transport of Uranium(VI) in Subsurface Media

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DIVISION S-2-SOIL CHEMISTRY

Adsorption and Transport of Uranium(VI) in Subsurface Media

M.O. Barnett^a, P.M. Jardine^b, S.C. Brooks^b and H.M. Selim^c

^a Dep. of Civil Engineering, 208 Harbert Engineering Center, Auburn Univ., Auburn, AL 36849-5337 USA
^b Environ. Sci. Div., Oak Ridge National Lab., P.O. Box 2008, Oak Ridge, TN 37831-6038 USA
^c Dep. of Agronomy, 104 Sturgis Hall, Louisiana State Univ., Baton Rouge, LA 70803 USA

barnettm{at}eng.auburn.edu

Uranium(VI) adsorption and transport in three natural, heterogeneoussubsurface media were investigated in batch and column experiments.The rate of U(VI) adsorption to the natural samples was rapidover the first few hours of the experiments, and then slowedappreciably after 24 to 48 h. The adsorption of U(VI) to thesamples was also nonlinear, suggesting a decreasing attractionfor the surface with increased surface loading. The extent ofadsorption on each of the media was strongly pH-dependent, increasingsharply as the pH increased from 4.5 to 5.5 and then decreasingsharply over the pH range 7.5 to 8.5 as the concentration ofdissolved carbonate and U(VI)–carbonate complexes increased.The similarities in the pH-dependent behavior between the threematerials despite differences in bulk mineralogy was likelydue to the similar Fe contents of the materials. The transportof U(VI) through packed columns of the soils and sediments wassignificantly retarded but reversible. The local equilibriumassumption and the batch-measured adsorption isotherms dramaticallyunderestimated the degree of retardation observed in the columns.The U(VI) displacement experiments were modeled with the one-dimensionaladvective–dispersive equation and several different modelformulations describing the interactions of U(VI) with the solidphase. These models were able to fit the observed breakthroughcurves within 0.1 root mean square error of the initial concentration.

Abbreviations: DOE, Department of Energy • FOK, first-order kinetic • FRK, fractional order kinetic • HF, Hanford • NLE, nonlinear equilibrium • OR, Oak Ridge • RMSE, root mean square error • SCM, surface complexation model • SR, Savannah River • XAS, x-ray absorption spectroscopy

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