(Project 6; Brusseau, Field) Acid rock drainage and its potential impact on surface-water and groundwater contamination is generally considered to be a primary environmental concern for many hardrock mining sites in the USA. Concomitantly, cost-effective treatment of mining-impacted waters to levels protective of human health and the environment is a critical issue for mitigating the risk associated with hardrock mining sites. The overall goals of this project are to investigate the key physical and biogeochemical processes that control migration and attenuation of mine- drainage contaminants in groundwater, and to develop and test innovative methods for characterization and remediation of contaminated groundwater at hardrock mining sites.
The specific aims of the project are: (1) Investigate the key processes that control migration and attenuation of mine-drainage contaminants at the source-groundwater interface; (2) Investigate the feasibility and long-term efficacy of in-situ biosequestration for the remediation of groundwater contaminated by acid-rock drainage; (3) Develop and apply integrated site characterization methods to evaluate groundwater contamination potential, assess risk, and determine the feasibility of remediation at mining sites. The project incorporates innovative hydrological and biogeochemical methods to develop approaches designed specifically for the unique properties and conditions inherent to mining sites in the Southwestern USA. The project targets the primary groundwater contaminants of concern at these sites, including sulfate, arsenic, selenium, perchlorate, and uranium. This project encompasses experiments conducted across several scales, from the pore-scale to the intermediate-scale to pilot-scale field tests. This project will advance the state of the science regarding the transport and attenuation of metalloids in the subsurface, and their remediation. For example, in-situ biosequestration is one of the very few options that exist for remediation of the large, deep groundwater contaminant plumes that form at hardrock mining sites. This method has great potential, but several critical questions exist as barriers to widespread acceptance and adoption. This project will answer these questions, with a specific focus on novel methods for implementing in- situ biosequestration under the conditions representative of sites in the Southwestern USA. It is anticipated that the application of project outcomes will produce significant cost savings for the clean-up of the nation's inventory of mine waste sites.

Public Health Relevance

(Project 6; Brusseau, Field) Acid rock drainage at hardrock mining sites creates surface-water and groundwater contamination that present major potential risks to human health and the environment. This project will investigate the transport and fate behavior of mine-drainage contaminants in groundwater, and it will develop and test innovative methods for characterization and remediation of contaminated groundwater. These efforts will help to reduce the risk of these sites, and will reduce the costs for their clean-up. We will work with the Research Translation Core to ensure that our research is appreciated and applied by the relevant Superfund stakeholders (e.g., EPA, ATSDR, as well as state, tribal and local regulatory agencies, the mining industry and communities, as appropriate).

Agency
National Institute of Health (NIH)
Institute
National Institute of Environmental Health Sciences (NIEHS)
Type
Hazardous Substances Basic Research Grants Program (NIEHS) (P42)
Project #
2P42ES004940-26
Application #
8918885
Study Section
Special Emphasis Panel (ZES1-LWJ-J (SF))
Project Start
Project End
Budget Start
2015-09-30
Budget End
2016-03-31
Support Year
26
Fiscal Year
2015
Total Cost
$153,645
Indirect Cost
$45,575
Name
University of Arizona
Department
Type
DUNS #
806345617
City
Tucson
State
AZ
Country
United States
Zip Code
85721
Khan, Muhammad Amjad; Ding, Xiaodong; Khan, Sardar et al. (2018) The influence of various organic amendments on the bioavailability and plant uptake of cadmium present in mine-degraded soil. Sci Total Environ 636:810-817
Yellowhair, Monica; Romanotto, Michelle R; Stearns, Diane M et al. (2018) Uranyl acetate induced DNA single strand breaks and AP sites in Chinese hamster ovary cells. Toxicol Appl Pharmacol 349:29-38
Fu, Xiaori; Dionysiou, Dionysios D; Brusseau, Mark L et al. (2018) Enhanced effect of EDDS and hydroxylamine on Fe(II)-catalyzed SPC system for trichloroethylene degradation. Environ Sci Pollut Res Int 25:15733-15742
Duncan, Candice M; Brusseau, Mark L (2018) An assessment of correlations between chlorinated VOC concentrations in tree tissue and groundwater for phytoscreening applications. Sci Total Environ 616-617:875-880
Virgone, K M; Ramirez-Andreotta, M; Mainhagu, J et al. (2018) Effective integrated frameworks for assessing mining sustainability. Environ Geochem Health 40:2635-2655
Namdari, Soodabeh; Karimi, Neamat; Sorooshian, Armin et al. (2018) Impacts of climate and synoptic fluctuations on dust storm activity over the Middle East. Atmos Environ (1994) 173:265-276
Hossein Mardi, Ali; Khaghani, Ali; MacDonald, Alexander B et al. (2018) The Lake Urmia environmental disaster in Iran: A look at aerosol pollution. Sci Total Environ 633:42-49
Dehghani, Mansooreh; Fazlzadeh, Mehdi; Sorooshian, Armin et al. (2018) Characteristics and health effects of BTEX in a hot spot for urban pollution. Ecotoxicol Environ Saf 155:133-143
Pu, Mengjie; Guan, Zeyu; Ma, Yongwen et al. (2018) Synthesis of iron-based metal-organic framework MIL-53 as an efficient catalyst to activate persulfate for the degradation of Orange G in aqueous solution. Appl Catal A Gen 549:82-92
Brusseau, Mark L; Guo, Zhilin (2018) The integrated contaminant elution and tracer test toolkit, ICET3, for improved characterization of mass transfer, attenuation, and mass removal. J Contam Hydrol 208:17-26

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