H33N-02
Seasonal Hydrologic Controls on Uranium and Iron Biogeochemistry in a Riparian Aquifer

Wednesday, 16 December 2015: 14:00
3018 (Moscone West)
Michael Wilkins1, Kenneth Hurst Williams2, Robert E Danczak1, Steven Yabusaki3, Yilin Fang4 and Chad Hobson2, (1)The Ohio State Univ, Columbus, OH, United States, (2)Lawrence Berkeley National Laboratory, Berkeley, CA, United States, (3)Pacific Northwest National Laboratory, Richland, WA, United States, (4)Battelle, Pacific Northwest National Laboratory, Richland, WA, United States
Abstract:
The maintenance of geochemically reducing conditions is generally optimal for the formation and preservation of reduced metals and mineral phases that can limit contaminant fate and transport. At a riparian aquifer near Rifle, CO, we tracked over six months the biogeochemical response within the aquifer to an annual pulse of dissolved oxygen (DO) that results from snowmelt-driven changes in Colorado River stage. In reduced portions of the aquifer (naturally reduced zones; NRZs) the re-oxidation of abundant iron sulfide minerals was the dominant oxygen-consuming process, and resulted in little DO intrusion into the deeper aquifer. In less reduced areas, DO intruded through the entire vertical profile of the aquifer. Across both regions, these perturbations resulted in changes to the microbial community structure, and aqueous metal pools. Two potentially different mechanisms of uranium mobilization were observed; (1) re-oxidation of reduced U(IV) phases in response to DO intrusion, and (2) mobilization of U(VI) from the vadose zone during water table rise. This high-resolution, long-term monitoring of aquifer biogeochemistry at the Rifle site has revealed dynamic microbial and geochemical responses to predictable, annual hydrologic perturbations, and offers an opportunity to further refine modeling approaches for such regions.