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Influence of Digestion Temperature on the Extraction of Soil Heavy Metal by Korean Ministry of Environment Standard Method
Gunhwan Shin·Hyunjung Park·Kiseok Oh·Gain Jung·Dongjun Shin·Goontaek Lee*·Changkyu Joo·Sangmo Lee·Taeseung Kim
National Instrumentation Center for Environmental Management, Seoul National University, Seoul 08826, Korea
토양오염공정시험기준에 따른 토양 중금속 추출 시 분해 온도가 미치는 영향
신건환·박현정·오기석·정가인·신동준·이군택*·주창규·이상모·김태승
서울대학교 농생명과학공동기기원
This article is an open access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

References

1. Adams, S.J. and Alloway, B.J., 1988, The effects of variations in temperature on the extraction of trace metals from soils by selected reagents, Environ. Technol. Lett., 9, 695-702.
2. Alghanmi, S.I., Al Sulami, A.F., El-Zayat, T.A., Alhogbi, B.G., and Salam, M.A., 2015, Acid leching of heavy metals from contaminated soil collected from Jeddah, Saudi Arabia: kinetic and thermodynamics studies, Int. Soil water Conserv. Res., 3, 196-208.
3. Aydinalp, C. and Marinova S., 2003, Distribution and forms of heavy metals in some agricultrual soils, Polish Journal of Envi. Stud, 12(5), 629-633.
4. Banta, K.M., Howari, F.M., and Al-Hamand, A.A., 2005, Heavy metals in urban soils of central Jordan: Should we worry about their environmental risk?, Environ. Res., 97, 258-273.
5. Chapman, H.D., 1965, Catuib-exchange capacity, In C.A.Black(ed). Methods of soil analysis part 2. chemical and microbiological properties. agron. monogr.9, ASA and SSSA, Madison, WI. 89-901.
6. Daldoul, G., Souissi, R., Souissi, F., Jemmali, N., and Chakroun, H.K., 2015, Assessment and mobility of heavy metals in carbonated soils contaminated by old mine tailings in North Tunisia, J. Afri. Ear. Sci., 110, 150-159.
7. De Matos, A.T., Fontes, M.P.F., Da Costa, L.M., and Martinez, M.A., 2001, Mobility of heavy metals as related to soil chemical and mineralogical characteristics of Brazilian soils, Environ. Pollut., 111, 429-435.
8. Gee, G.W. and Bauder, J.W., 1986, In: Klute, Method of soil analysis part I. partical size analysis, Amer. Soci. agron. Madison, WI. 383-411.
9. Guedes, L.G., Melo, V.F., and Batista, A.H., 2020, The classic aqua regia and epa 3051a method can mislead environmental assessments and certification: potentially harmful elements resorption in short-range order materials, Chemosp.,251, 126356.
10. International organization for standardization (ISO), 1995, Soil quality-extraction of trace elements soluble in aqua regia, ISO 11466.
11. International organization for standardization (ISO), 2005, Certification of reference materials-general and statistical principles, ISO Guide 35.
12. International organization for standardization (ISO), 2012, Soil quality-microwave-assisted extraction of the aqua regia soluble fraction for the determination of elements, ISO 12914.
13. International organization for standardization (ISO), 2020, Soil, treated biowaste, sludge and waste-digestion of aqua regia soluble fractions of elements, ISO 54321.
14. Jeong, T.K., Cho, E.J., Jeong, J.E., Ji, H.S., Lee, K.S., Yoo., P.J., Kim, G.G., Choi, J.Y., Park, J.H., Kim, S.H., Heo, J.S., and Seo, D.C., 2015, Soil contamination of heavy metals in national industrial complexes Korea, Kor. Envi. Agric., 34(2), 69-76.
15. Jung, M.C. and Jung, M.Y., 2006, Evaluation and management method of environmental contamination from abandoned metal mines in Korea, J. Soci. Min. Eng. RES. Eng., 43(5), 383-394.
16. Kelepertzis, E. and Stathopoulou, E., 2013, Availability of geogenic heavy metal in soils of thiva town(central Greece), Environ. Monit. Assess, 185, 9603-9618.
17. Kierczak, J., Neel, C., and Puziewicz, J., 2007, Effect of mineralogy and pedoclimatic variations on Ni and Cr distribution in serpentine soils under temperate climate, Geoderma,2(1-2), 165-177.
18. Kierczak, J., Pedziwiatr, A., Waroszewski, J., and Modelska, M., 2016, Mobility of Ni, Cr and Co in serpentine soils derived on various ultrabasic bedrocks under temperate climate, Geoderma, 268, 78-91.
19. Korean Ministry of Environment Standard (KMES), Notification, No.2018-53(2018.12.07), Republic of Korea.
20. Lee, D.Y., Jung, S.K., and Son, Y.G., 2018, Heavy metals extraction from contaminated soils using aqua regia extraction, J. Soil. Groundw. Environ., 23(2), 15-22.
21. Lee, H.G., Kim, J.I., Noh, H.J., Park, J.E., Kim, T.S., and Yoon, J.K., 2016, Correlation estimation between geochemical metal-fraction and soil properties in agricultural and industrial soils, J. Soil. Groundw. Environ., 21(6), 1-10.
22. Lee, S.W., Lim, T.Y., Park, M.J., Lee, S.H., Cha, J.M., and Kim, S.O., 2015, Study on exposure factors and model specialized for human risk assessment of abandoned mine area, Korea, J. Korean Soc. Miner. Energy Resour. Eng., 52(5), 488-499.
23. Lima, E., Sobrinho, N., Perez, D., and Coutinho L., 2016, Comparing method for extracting heavy metals from histosols for establishing quality reference values, Rev. Bras. Solo., Division.
24. Mocko, A. and Waclawek, W., 2004, Three-step extraction procedure for determination of heavy metals availability to vegetables, Anal. Bioanal. Chem., 380, 813-817.
25. National Institute of Environmental Reserch (NIER) 2021, Notification, No.2021-67, Republic of Korea.
26. Oh, S. and Yoon, M., 2015, Chemical extraction of arsenic and heavy metals from contaminated soils under high temperature and pressure conditions in abandoned mines in South Korea, Soil Sediment Contam. Int. J., 24, 423-436.
27. Peña-Icart, M., Margarita, E., Tagle, V., Alonso-Hernandez, C., Hernandez, J. R., Behar, M., Maro, S., and Alfonso, P., 2011, Comparative study of digestion methods EPA 3050B(HNO₃-H₂O₂-HCl) and ISO 11466.3 (aqua regia) for Cu, Ni and Pb contamination assessment in marine sediments, Mari. Envir. Rese., 72, 60-66.
28. Quantin, C., Ettler, V., Garnier, J., and Šebek, O., 2008, Sources and extractibility of chromium and nikel in soil profiles developed on Czech serpentinites, Comp. Ren. Gepsci., 340, 872-882.
29. Santoro, A., Held, A., Linsinger, T.P., Perez, A., and Ricci M., 2017, Comparison of total and aqua regia extractability of heavy metals in sewage sludge: the case study of a certified reference material, Tren. Analy. Chemi., 89, 34-40.
30. Shin, G.W., Lee, G.T., Lee, W.S., Kim, J.I., Kim, B.K., and Park, H.J., 2012, Assessment for the comparability between korean ministry of environment standard and iso standard for the determination of heavy metals in soil, J. Soil. Groundw. Environ., 17(3), 1-9.
31. Tills, A.R. and Alloway, B.J., 1983, The speciation of lead in soil solution from very polluted soils., Environmental Technology Letters, 4, 529-534.
32. United States Environmental protection agency (EPA), 1994, Acid digestion of Sediments, Sludges and Soil, SW846 Method 3051.
33. United States Environmental protection agency (EPA), 1996, Acid digestion of Sediments, Sludges and Soil, SW846 Method 3050B.
34. United States Environmental protection agency (EPA), 1996, microwave Assisted Acid digestion of Siliceous and Organically Based Matrice, SW846 Method 3052.
35. United States Environmental protection agency (EPA), 2007, microwave Assisted Acid digestion of Sediments, Sludges, Soil and Oils, SW846 Method 3051A.
36. Walkley, A. and Black, I., 1934, An examination of degtiareff method for determining soil organic matter and a proposed modification of the chromic acid titration method, Soil Sci., 37, 29-37.

This Article

2022; 27(3): 11-21

Published on Jun 30, 2022
10.7857/JSGE.2022.27.3.011
Received on Mar 30, 2022
Revised on Mar 31, 2022
Accepted on May 10, 2022

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Correspondence to

Goontaek Lee
National Instrumentation Center for Environmental Management, Seoul National University, Seoul 08826, Korea
E-mail: gtlee@snu.ac.kr