H33N-04
Column Testing and 1D Reactive Transport Modeling to Evaluate Uranium Plume Persistence Processes

Wednesday, 16 December 2015: 14:40
3018 (Moscone West)
Raymond H Johnson1, Stan Morrison1, Sarah Morris1, Aaron Tigar1, William L Dam2 and Jalena Dayvault2, (1)Navarro Research and Engineering, Contractor for the U.S. Department of Energy Office of Legacy Management, Grand Junction, CO, United States, (2)U.S. Department of Energy Office of Legacy Management, Grand Junction, CO, United States
Abstract:
At many U.S. Department of Energy Office of Legacy Management sites, 100 year natural flushing was selected as a remedial option for groundwater uranium plumes. However, current data indicate that natural flushing is not occurring as quickly as expected and solid-phase and aqueous uranium concentrations are persistent. At the Grand Junction, Colorado office site, column testing was completed on core collected below an area where uranium mill tailings have been removed. The total uranium concentration in this core was 13.2 mg/kg and the column was flushed with laboratory-created water with no uranium and chemistry similar to the nearby Gunnison River. The core was flushed for a total of 91 pore volumes producing a maximum effluent uranium concentration of 6,110 µg/L at 2.1 pore volumes and a minimum uranium concentration of 36.2 µg/L at the final pore volume. These results indicate complex geochemical reactions at small pore volumes and a long tailing affect at greater pore volumes. Stop flow data indicate the occurrence of non-equilibrium processes that create uranium concentration rebound. These data confirm the potential for plume persistence, which is occurring at the field scale. 1D reactive transport modeling was completed using PHREEQC (geochemical model) and calibrated to the column test data manually and using PEST (inverse modeling calibration routine). Processes of sorption, dual porosity with diffusion, mineral dissolution, dispersion, and cation exchange were evaluated separately and in combination. The calibration results indicate that sorption and dual porosity are major processes in explaining the column test data. These processes are also supported by fission track photographs that show solid-phase uranium residing in less mobile pore spaces. These procedures provide valuable information on plume persistence and secondary source processes that may be used to better inform and evaluate remedial strategies, including natural flushing.