Assessment of Downhole Membrane-Diffused Hydrogen for Stimulating Uranium Reduction and Immobilization

Wednesday, September 23, 2015: 9:10 a.m.
Lewis Haynes , Environmental Engineering, Texas A&M University-Kingsville, Kingsville, TX
Lee Clapp, Ph.D., P.E. , Environmental Engineering, Texas A&M University-Kingsville, Kingsville, TX

The most common technology currently used for restoring groundwater at in-situ recovery (ISR) uranium mining sites is reverse osmosis and reinjection of the permeate. However, this practice does not restore the formation to its original reduced state, and in many cases groundwater uranium concentrations are not restored to pre-mining baseline levels. This study was performed to evaluate the effectiveness of introducing dissolved hydrogen into a post-mined formation at an ISR mining site to stimulate reduction and immobilization of residual soluble uranium. The main objectives of this research project were: (1) to develop and optimize a system for minimizing air entrainment during water injection when employing a membrane gas-transfer device for downhole hydrogen infusion; and (2) to assess whether injecting dissolved hydrogen using the membrane gas-transfer device can promote immobilization of dissolved uranium in groundwater to near or below pre-mining concentrations. Approximately 15,000 gallons of groundwater were pumped to the surface and then re-injected into the subsurface while being supplied with dissolved hydrogen using the downhole membrane gas infusion device. The groundwater was pumped back to the surface after several months to evaluate the extent to which dissolved uranium had been removed. Initial results indicate an approximately 80% reduction in soluble uranium concentration was achieved. Microbial analyses indicated a significant increase in iron-reducing bacteria, but less significant increases in sulfate-reducing bacteria. A bromide tracer study was performed concurrently with the hydrogen injection study so that the effective zone of influence of the push-pull test could be estimated, while pump tests were performed before and after the hydrogen injection study so the effect of the injected hydrogen on the formation permeability could also be assessed.

Lewis Haynes, Environmental Engineering, Texas A&M University-Kingsville, Kingsville, TX
Lewis Haynes is a Ph.D. candidate in Environmental Engineering at Texas A&M University-Kingsville.


Lee Clapp, Ph.D., P.E., Environmental Engineering, Texas A&M University-Kingsville, Kingsville, TX
Lee Clapp, Ph.D., PE, is a Professor in Environmental Engineering at Texas A&M University-Kingsville.