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http://dx.doi.org/10.9720/kseg.2013.2.171

Geochemical Occurrence of Uranium and Radon-222 in Groundwater at Test Borehole Site in the Daejeon area  

Jeong, Chan Ho (Dept. of Geotechnical Engineering, Daejeon University)
Ryu, Kun Seok (Dept. of Geotechnical Engineering, Daejeon University)
Kim, Moon Su (National Institute of Environmental Research)
Kim, Tae Sung (National Institute of Environmental Research)
Han, Jin Suk (National Institute of Environmental Research)
Jo, Byung Uk (Korea Institute of Geoscience and Mineral Resources)
Publication Information
The Journal of Engineering Geology / v.23, no.2, 2013 , pp. 171-186 More about this Journal
Abstract
A drilling project was undertaken to characterize the geochemical relationship and the occurrence of radioactive materials at a test site among public-use groundwaters previously known to have high occurrence of uranium and radon-222 in the Daejeon area. A borehole (121 m deep) was drilled and core rocks mainly consist of two-mica granite, and associated with pegmatite and dykes of intermediate composition. The groundwater samples collected at six different depths in the borehole by a double-packed system showed the pH values ranging from neutral to alkaline (7.10-9.3), and electrical conductivity ranging from 263 to 443 ${\mu}S/cm$. The chemical composition of the borehole groundwaters was of the $Ca-HCO_3(SO_4+Cl)$ type. The uranium and Rn-222 contents in the groundwater were 109-1,020 ppb and 9,190-32,800 pCi/L, respectively. These levels exceed the regulation guidelines of US EPA. The zone of the highest groundwater uranium content occurred at depths of 45 to 55m. The groundwater chemistry in this zone (alkaline, oxidated, and high in bicarbonate) is favorable for the dissolution of uranium into groundwater. The dominant uranium complex in groundwater is likely to be $(UO_2CO_3)^0$ or $(UO_2HCO_3)^+$. Radon-222 content in groundwater shows an increasing trend with depth. The uranium and thorium contents in the core were 0.372-47.42 ppm and 0.388-11.22 ppm, respectively. These levels are higher values than those previously been reported in Korea. Microscopic observations and electron microprobe analysis(EPMA) revealed that the minerals containing U and Th are monazite, apatite, epidote, and feldspar. U and Th in these minerals are likely to substitute for major elements in crystal lattice.
Keywords
Double packer; groundwater; two-mica granite; radioactive materials; drilling core;
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Times Cited By KSCI : 3  (Citation Analysis)
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