H33N-01
Utilizing hydrologic, statistical, and geochemical tools to assess uranium mobility in surface and near-surface environments
Wednesday, 16 December 2015: 13:40
3018 (Moscone West)
David L Naftz, U.S. Geological Survey, Helena, MT, United States, Katherine E Walton-Day, U.S. Geological Survey, Denver, CO, United States, Christopher Fuller, USGS Western Regional Offices Menlo Park, Menlo Park, CA, United States, William L Dam, Department of Energy Grand Junction, Grand Junction, CO, United States, Martin A Briggs, USGS Groundwater Information, Reston, VA, United States and Terry Snyder, BLM, Salt Lake City, UT, United States
Abstract:
Legacy uranium (U) mining and processing activities have resulted in soil and water contamination on Federal, state, and tribal lands in the western United States. Sites include legacy mill sites associated with U extraction now managed by the Department of Energy and thousands of waste dumps associated with U exploration, mining, and processing. Recently (2012), over 400,000 hectares of federally managed land in northern Arizona was withdrawn from consideration of mining for a 20-year period to protect the Grand Canyon watershed from potentially adverse effects of U mineral exploration and development. Ore from active and recently active U mines in the Colorado Plateau, the Henry Mountains Complex, and the Arizona Strip is transported to the only currently (2015) active conventional mill site in the western United States, located in Utah. Previous and ongoing U.S. Geological Survey assessments to examine U mobility at a variety of legacy and active sites associated with ore exploration, extraction, and processing will be presented as field-scale examples. Topics associated with site investigations will include: (1) offsite migration of radionuclides associated with the operation of the White Mesa U mill; (2) long-term contaminant transport from legacy U waste dumps on Bureau of Land Management regulated land in Utah; (3) application of incremental soil sampling techniques to determine pre- and post-mining radionuclide levels associated with planned and operating U mines in northern Arizona; (4) application of fiber optic digital temperature sensing equipment to identify areas where shallow groundwater containing elevated U levels may be discharging to a river adjacent to a reclaimed mill site in central Wyoming; and (5) field-scale manipulation of groundwater chemistry to limit U migration from a legacy upgrader site in southeastern Utah.