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Development of Appropriate Acid Digestion Method used for the Determination of Total Uranium in Soil by Inductively Coupled Plasma-Mass Spectrometer (ICP-MS)
Shin, Gunhwan;Lee, Goontaek;Kang, Jiyoung;Yoon, Jungki;Kim, Hyunkoo;Noh, Hoejung;Kim, Jiin;Kim, Kyehoon;
NICEM, Seoul National University;NICEM, Seoul National University;NICEM, Seoul National University;National Institute of Environmental Research;National Institute of Environmental Research;National Institute of Environmental Research;National Institute of Environmental Research;Department of Environmental Horticulture, University of Seoul;
유도결합플라즈마-질량분석기(ICP-MS)를 이용한 토양의 총 우라늄 정량에 요구되는 적정 산분해 전처리 방법 개발
신건환;이군택;강지영;윤정기;김현구;노회정;김지인;김계훈;
서울대학교 농업생명과학대학 농생명과학공동기기원;서울대학교 농업생명과학대학 농생명과학공동기기원;서울대학교 농업생명과학대학 농생명과학공동기기원;국립환경과학원 토양지하수연구과;국립환경과학원 토양지하수연구과;국립환경과학원 토양지하수연구과;국립환경과학원 토양지하수연구과;서울시립대학교 환경원예학과;

References

1. ASTM (American Society for Testing and Materials), 2001, Standard Test Method for Analysis of Total and Isotopic Uranium and Total Thorium in Soils by Inductively Coupled Plasma-mass Spectrometry, ASTM Standard C1345-96.
2. Barrett, C.A., Chouyyok, W., Speakman, R.J., Olsen, K.B., and Addleman, R.S., 2017, Rapid extraction and assay of uranium from environmental surface samples, Talant., 173, 69-78.
3. Bartova, H., Kucera, J., Musilek, L., Trojek, T., and Gregorova, E., 2017, Determination of U, Th and K in bricks by gamma-ray spectrometry, X-ray fluorescence analysis and neutron activation analysis, Radiat. Physi. and Chemist., 140, 161-166.
4. Bigalke, M., Schwab, L., Rehmus, A., Tondo P., and Flisch, M., 2018, Uranium in agricultural soils and drinking water wells on the swiss plateau, Environ. Pollu., 233, 943-951.
5. Dirican, A. and Sahin, M., 2016, Comparison of acid leaching and fusion techniques to determine uranium in soil samples by alpha spectrometry, Appl. Radia. and Isoto., 109, 189-192.
6. Favas, P.J.C. and Pratas, J., 2014, Uranium bioavailability and environmental risk assessment in soils contaminated by mining, Ier. proce., 9, 43-46.
7. Frances, F.S., Pacheco, E.G., Grana. A.M., Rojo, P.A., Zarza, C.A., and Sanchez, A.G., 2018, Concentration of uranium in the soils of the west of spain, Environ. Pollut., 236, 1-11.
8. ISO (International Standardization Organization), 1995, Soil quality-extraction of trace elements soluble in aqua regia, ISO standard 11466.
9. ISO (International Standardization Organization), 2005a, Measurement of radioactivity in the environment soil, part 1: general guidelines and definitions, ISO standard 18589-1.
10. ISO (International Standardization Organization), 2005b, Certification of reference materials-general and statistical principles, ISO standard guide 35.
11. Jurecic, S., Benedik, L., Planinsek, P., Necemer, M., Kump, P., and Pilhlar, B., 2014, Analysis of uranium in the insoluble residues after decomposition of soil samples by various techniques, Appl. Radia. and Isoto., 87, 61-65.
12. Kim, C.J., Cho, Y.H., Chae, J.S., and Yun, J.Y., 2012, Efficient sample digestion method determination in soil using microwave digestion for alpha spectrometry, Radiati. Protect., 37(4), 213-218.
13. KMOE (Korean Ministry of Environment), 2015, Guideline for Drinking Water, Notification, No.2015-214, Republic of Korea.
14. Landsberger, S. and Kapsimalis, R., 2013, Comparison of neutron activation analysis techniques for the determination of uranium concentrations in geological and environmental materials, Environ. Radioactiv., 117, 41-44.
15. Lee, H.W., Lim, J.M., Lee, H., Park, J.Y., Jang. M., and Lee, J.H., 2018, Study on the determination methods of the natural radionuclides ($^{238}U$, $^{232}Th$) in building materials and processed living products, Analy. Sci. Techn., 31(3), 149-160.
16. Mantero, J., Lehritane, M., Hurtado, S., and Garcia-Tenorio, R., 2010, Radioanalutical determination of actinoids in refractory matrices by alkali fusion, Radio. Nucl. Chem., 286, 557-563.
17. Mccormick, A., 1992, Thermal-ionization mass spectrometry for small sample analysis of uranium and plutonium, Appl. Radial. Isol., 43, 271-278.
18. Park, C.S., Shin, H.S., Oh, H., Moon, J.H., Cho, H., and Cheong, C.S., 2012, Determination of trace elements in geological reference materials G-3, GSP-2 and SGD-1 a by low-dilution glass bead digestion and icp-ms, Geostand. and Geoanalyti. Resear., 37, 361-368.
19. Park, J.Y., Lim, J.M., Lee, H.W., and Lee, W., 2018, Establishing of a rapid analytical method uranium isotopic ratios for environmental monitoring around nuclear facilities, Analy. Sci. Techn., 31(3), 134-142.
20. Park, S.I., and Oh, T.H., 2010, The application of analysis of variance (ANOVA), Vet. Clin., 27(1), 71-78.
21. Rodriguez, P.B., Tome, F.V., and Lozano, J.C., 2001, Concerning the low uranium and thorium yields in the electrodeposition process of soil and sediment analyses, Appli. Radiat. Isotop., 54, 29-33.
22. Saleh, I.H. and Abdel-Halim, A.A., 2016, Determination of depleted uranium using a high-resolution gamma-ray spectrometer and its applications in soil and sediments, Taib. Univer. Scien., 10, 205-211.
23. United nations scientific committee on the effects of atomic radiation (UNSCEAR), 2000, Sources and effects of ionizing radiation, report, united nations, new work.
24. USEPA (United States Environmental Protection Agency), 1994, Synthetic Leaching Procedure, SW-846 : Test Methods for Evaluating Solid Waste Physical/Chemical Methods, EPA method 3051.
25. USEPA (United States Environmental Protection Agency), 1996, Synthetic Leaching Procedure, SW-846 : Test Methods for Evaluating Solid Waste Protection Physical/Chemical Methods, EPA method 3052.
26. USEPA (United States Environmental Protection Agency), 2007, Synthetic Leaching Procedure, SW-846 : Test Methods for Evaluating Solid Waste Physical/Chemical Methods, EPA method 3051A.

This Article

2018; 23(6): 73-81

Published on Dec 31, 2018
10.7857/JSGE.2018.23.6.073
Received on Nov 6, 2018
Accepted on Nov 30, 2018

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