Characterization of U(VI) Sorption-Desorption Processes and Model Upscaling
- Johns Hopkins University
The objectives of the overall collaborative EMSP effort (with which this project is associated) were to characterize sorption and desorption processes of U(VI) on pristine and contaminated Hanford sediments over a range of sediment facies and materials properties and to relate such characterization both to fundamental molecular-scale understanding and field-scale models of geochemistry and mass transfer. The research was intended to provide new insights on the mechanisms of U(VI) retardation at Hanford, and to allow the development of approaches by which laboratory-developed geochemical models could be upscaled for defensible field-scale predictions of uranium transport in the environment. Within this broader context, objectives of the JHU-based project were to test hypotheses regarding the coupled roles of adsorption and impermeable-zone diffusion in controlling the fate and transport of U(VI) species under conditions of comparatively short-term exposure. In particular, this work tested the following hypotheses: (1) the primary adsorption processes in the Hanford sediment over the pH range of 7 to 10 are surface complexation reactions of aqueous U(VI) hydroxycarbonate and carbonate complexes with amphoteric edge sites on detrital phyllosilicates in the silt/clay size fraction; (2) macroscopic adsorption intensity (at given aqueous conditions) is a function of mineral composition and aquatic chemistry; and (3) equilibrium sorption and desorption to apply in short-term, laboratory-spiked pristine sediments; and (4) interparticle diffusion can be fully understood in terms of a model that couples molecular diffusion of uranium species in the porewater with equilibrium sorption under the relevant aqueous conditions. The primary focus of the work was on developing and applying both models and experiments to test the applicability of "local equilibrium" assumptions in the modeling interpretation of sorption retarded interparticle diffusion, as relevant to processes of U(VI) diffusion in silt/clay layers. Batch isotherm experiments were first used to confirm sorption isotherms under the intended test conditions and diffusion cell experiments were then conducted to explore the diffusion hypotheses. Important new information was obtained about the role of aqueous calcium and solid calcium carbonate in controlling sorption equilibrium with Hanford sediments. The retarded interparticle diffusion model with local sorption equilibrium was shown to very successfully simulate diffusion at high aqueous concentration of U(VI). By contrast, however, diffusion data obtained at low concentration suggested nonequilibrium of sorption even at diffusion time scales. Such nonequilibrium effects at low concentration are likely to be the result of sorption retarded intraparticle diffusion, and strong U(VI) sorption in the low concentration range.
- Research Organization:
- Johns Hopkins University, 3400 N. Charles St., Baltimore, MD 21218
- Sponsoring Organization:
- USDOE - Office of Environmental Management (EM)
- DOE Contract Number:
- FG07-02ER63498
- OSTI ID:
- 894270
- Report Number(s):
- DOE/ER63498; EMSP 86748
- Country of Publication:
- United States
- Language:
- English
Similar Records
Study of sorption-retarded U(VI) diffusion in Hanford silt/clay material
Kinetic Desorption and Sorption of U(VI) During Reactive Transport in a Contaminated Hanford Sediment
Influence of Calcite and Dissolved Calcium on Uranium(VI) Sorption to a Hanford Subsurface Sediment
Journal Article
·
Thu Oct 15 00:00:00 EDT 2009
· Environmental Science & Technology, 43(20):7706-7711
·
OSTI ID:966638
Kinetic Desorption and Sorption of U(VI) During Reactive Transport in a Contaminated Hanford Sediment
Journal Article
·
Thu May 12 00:00:00 EDT 2005
· Environmental Science and Technology, 39(9):3157-3165
·
OSTI ID:15016599
Influence of Calcite and Dissolved Calcium on Uranium(VI) Sorption to a Hanford Subsurface Sediment
Journal Article
·
Sat Oct 15 00:00:00 EDT 2005
· Environmental Science and Technology
·
OSTI ID:876977