Surface geophysical exploration: developing noninvasive tools to monitor past leaks around Hanford’s tank farms

A characterization program has been developed at Hanford to image past leaks in and around the underground storage tank facilities. The program is based on electrical resistivity, a geophysical technique that maps the distribution of electrical properties of the subsurface. The method was shown to b...

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Bibliographic Details
Published in:Environmental monitoring and assessment 2013, Vol.185 (1), p.995-1010
Main Authors: Rucker, Dale F., Myers, David A., Cubbage, Brian, Levitt, Marc T., Noonan, Gillian E., McNeill, Michael, Henderson, Colin, Lober, Robert W.
Format: Article
Language:English
Subjects:
Animal, plant and microbial ecology
Applied ecology
Atmospheric Protection/Air Quality Control/Air Pollution
Biological and medical sciences
Boreholes
Conservation, protection and management of environment and wildlife
Contaminants
Contamination
Earth and Environmental Science
Ecology
Ecotoxicology
Electrical properties
Electrical resistivity
Electrodes
Environment
Environmental Management
Environmental monitoring
Environmental Monitoring - methods
Fundamental and applied biological sciences. Psychology
Geophysical exploration
Groundwater
Infrastructure
Methods
Monitoring/Environmental Analysis
Quality assurance
Refuse Disposal - methods
Remote Sensing Technology
Sensors
Software
Soil Pollutants - analysis
Underground storage
Waste disposal
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Summary:A characterization program has been developed at Hanford to image past leaks in and around the underground storage tank facilities. The program is based on electrical resistivity, a geophysical technique that maps the distribution of electrical properties of the subsurface. The method was shown to be immediately successful in open areas devoid of underground metallic infrastructure, due to the large contrast in material properties between the highly saline waste and the dry sandy host environment. The results in these areas, confirmed by a limited number of boreholes, demonstrate a tendency for the lateral extent of the underground waste plume to remain within the approximate footprint of the disposal facility. In infrastructure-rich areas, such as tank farms, the conventional application of electrical resistivity using small point-source surface electrodes initially presented a challenge for the resistivity method. The method was then adapted to directly use the buried infrastructure, specifically the steel-cased wells that surround the tanks, as “long” electrodes for both transmission of electrical current and measurements of voltage. Overcoming the drawbacks of the long electrode method has been the focus of our work over the past 7 years. The drawbacks include low vertical resolution and limited lateral coverage. The lateral coverage issue has been improved by supplementing the long electrodes with surface electrodes in areas devoid of infrastructure. The vertical resolution has been increased by developing borehole electrode arrays that can fit within the small-diameter drive casing of a direct push rig. The evolution of the program has led to some exceptional advances in the application of geophysical methods, including logistical deployment of the technology in hazardous areas, development of parallel processing resistivity inversion algorithms, and adapting the processing tools to accommodate electrodes of all shapes and locations. The program is accompanied by a full set of quality assurance procedures that cover the layout of sensors, measurement strategies, and software enhancements while insuring the integrity of stored data. The data have been shown to be useful in identifying previously unknown contaminant sources and defining the footprint of precipitation recharge barriers to retard the movement of existing contamination.
ISSN:0167-6369
1573-2959
DOI:10.1007/s10661-012-2609-x