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2017 Vol.50, Issue 4 Preview Page
Evaluation on Four Volatile Organic Compounds (VOCs) Contents in the Groundwater and Their Human Risk Level
Dahee Song
,
Sunhwa Park
,
Sang-Ho Jeon
,
Jong Yeon Hwang
,
Moonsu Kim
,
Hun-Je Jo
,
Deok-Hyun Kim
,
Gyeong-Mi Lee
,
Ki-In Kim1
,
Hye-Jin Kim
,
Tae-Seung Kim
,
Hyen Mi Chung
,
Hyun-Koo Kim*
,
,
,
,
,
,
,
,
,
,
,
,
National Institute of Environmental Research
1Horticultural Science Department, Mokpo National University
*Corresponding Author. 
August 2017. pp. 235-250
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Abstract

In this study, we monitored 4 volatile organic compounds (VOCs) such as chloroform, dichloromethane, 1,2-dichloroethane, and tetrachloromethane in groundwater samples to determine the detection frequency and their concentrations and evaluated the health risk level considering ingestion, inhalation, and skin contact. 75 groundwater wells were selected. 24 wells were from monitoring background groundwater quality level and 51 wells were from monitoring groundwater quality level in industrial or contamination source area. In the results, the detection frequency for chloroform, dichloromethane, 1,2-dichloroethane, and tetrachloromethane was 42.3%, 8.1%, 6.0%, and 3.4%, respectively. The average concentrations of VOCs were high in the order of chloroform (1.7 µg L-1), dichloromethane (0.08 µg L-1), tetrachloromethane (0.05 µg L-1), and 1,2-dichloroethane (0.05 µg L-1). Chloroform had the highest detection frequency and average detection concentration. In the contaminated groundwater, the detection frequency of VOCs was high in the order of chloroform, dichloromethane, 1,2-dchloroethane, and tetrachloromethane. The average concentrations for chloroform, dichloromethane, 1,2-dichloroethane, and tetrachloromethane were 2.23 µg L-1, 0.08 µg L-1, 0.07 µg L-1, and 0.06 µg L-1, respectively. All the 4 compounds were detected at industrial complex and storage tank area. The maximum concentration of chloroform, dichloromethane, and 1,2-dichloroethane was detected at industrial complex area. Especially, the maximum concentration of chloroform and dichloromethane was detected at a chemical factory area. In the uncontaminated groundwater, the detection frequency of VOCs was high in the order of chloroform, dichloromethane, and 1,2-dchloroethane and tetrachloromethane was not detected. The average concentrations for chloroform, dichloromethane, and 1,2-dichloroethane were 0.57 µg L-1, 0.07 µg L-1, and 0.03 µg L-1, respectively. Although chloroform in the uncontaminated groundwater was detected the most, the concentration of chloroform was not exceeding water quality standards. By land use, the maximum detection frequency of 1,2-dichloroethane was found near a traffic area. For human risk assessment, the cancer risk for the 4 VOCs was 10-6~10-9, while the non-cancer risk (HQ value) for the 4 VOCs is 10-2~10-3.

Detection frequency and average concentration of VOCs in the contaminated groundwater.

Keywords
Chloroform
Dichloromethane
Groundwater
1,2-Dichloroethane
Risk assessment
Tetrachloromethane
Volatile Organic Compounds (VOCs)

References
1
American Society for Testing and Material. 2010. E1739-95 Standard guide for risk-based corrective action applied at petroleum release. United States.
2
American Society for Testing and Material. 2012. D5790-95 Standard test method for measurement of permeable organic compounds in water by capillary column gas chromatograph/mass spectrometry. United States.
3
Bender, D.A., T.S. Zogorski, M.J. Halde, and B.L. Rowe. 1999. selection procedure and salient information for Volatile Organic Compounds emphasized in the national water-quality assessment program. USGS Open-File Report. Denver.
4
Cho, B.W., U. Yun, H.C. Im, I.H. Sung, and W.S. Jang. 2005. Characteristics of groundwater, sewage water and stream water contamination based on VOCs concentration around Ulsan, Korea. Econ. Environ. Geol. 38(1): 57-65.
5
Cho, C.H. and Sung, K.J. 2013. The characteristics of shallow groundwater in petroleum contaminated site and the assessment of efficiency of biopile by off-gas analysis. J. Soil Groundwater Environ. 18(2):36-44.
6
Hwang, S.H., W.Y. Kwon, H.K. Kim, T.S. Kim, S.K. Kim, J.H. Choi, and H.S. Pyo. 2010. Monitoring and risk assessment of disinfection by-products found in chlorinated drinking water in Korea. J. Korean Soc. Environ. Anal. 13(1):11-20.
7
International Organization for Standardization. 2003. 15680 Water quality - Gas-chromatographic determination of a number of monocyclic aromatic hydrocarbons, naphthalene and several chlorinated compounds using purge-and- trap and thermal desorption. Geneva.
8
International Organization for Standardization. 2009. 5667-11 Water quality - Sampling - Part 11: Guidance on Sampling of Groundwaters. Geneva.
9
International Organization for Standardization. 2012. 5667-3 Water quality - Sampling - Part 3: Preservation and Handling of Water Samples. Geneva.
10
IRIS. 2017. Integrated risk information system, http://www.epa.gov/iris/.
11
Jeon, S.R., J.I. Chung, and D.H. Kim. 2001. Environmental effects from natural waters contaminated with acid mine drainage in the abandoned Backen mine area. Econ. Environ. Geol. 35(3):325-337.
12
Kwak, S.Y., H.S. Pyo, and S.J. Park. 2005. The analysis of trihalomethanes in water sample by purge-and-trap gas chromatograph/mass spectrometer and risk assessment. J. Environ. Toxicol. 20(1):29-37.
13
Lee, I.G. and S.H. Choi. 2009. Characteristics of groundwater quality according to types of aquifers in Okcheon area. Bull. Nat. Sci. 23:27-31.
14
Lee, P.G., S.W. Park, W.C. Jeon, and S.C. Shin. 2001. Volatile Organic Compounds contamination in some urban runoff and groundwater samples in Seoul city. J. Korean Soc. Soil Groundwater Environ. 6(3):73-91.
15
Lee, S.Y., J.M. Oh, M.H. Baik, and Y.J. Lee. 2011. Change of oxidation/reduction potential of solution by metal- reducing bacteria and roles of biosynthesized Mackinawite. J. Mineral. Soc. Korea 21(4):279-287.
16
Lopes, T.J. and S.G. Dionne. 1998. A review of semivolatile and Volatile Organic Compounds in highway runoff and urban stormwater. USGS Open-File Report. Denver.
17
Ministry of Environment. 2007. Korean exposure factors handbook. Korea.
18
Ministry of Environment. 2012. Official test method of drinking water. Korea.
19
Ministry of Environment. 2014. Official test method of water pollution. Korea.
20
Ministry of Environment. 2016. 2015 Environmental statistics yearbook. Korea.
21
Ministry of Environment. 2016. 2016 White paper of environment. Korea.
22
Ministry of Environment. 2017. Environmental Geographic information system. http://egis.me.go.kr/.
23
Ministry of Land, Infrastructure and Transport. 2016. 2016 Groundwater annual report. Korea.
24
National Institute of Environmental Research. 2017. Chemicals information system. http://ncis.nier.go.kr/.
25
National Research Council. 1983. Risk assessment in the federal government: managing the process. National Academy Press. Washington, D.C.
26
RAIS. 2017. Risk assessment information system. http://rais.ornl.gov/.
27
Seoul Metropolitan Government. 2013. 2012 White paper: Seoul’s environmental. Seoul. Korea.
28
US EPA. 1989. Risk assessment guidance for superfund: Volume I - human health evaluation manual (Part A), interim final. Washington, D.C.
29
US EPA. 1991. Risk assessment guidance for superfund: Volume I - human health evaluation manual (Part B, development of risk-based preliminary remediation goals), interim. Washington, D.C.
30
US EPA. 1992. Method 524.2 measurement of permeable organic compounds in water by capillary column gas chromatography/mass spectrometry. United State.
31
US EPA. 2004. Risk assessment guidance for superfund: Volume I - human health evaluation manual (Part E, supplemental guidance for dermal risk assessment), final. Washington, D.C.
32
US Massachusetts. 2004. Identification of applicable groundwater standards in method 1 (310 CMR 40.0974). massachusetts.
33
WHO. 2006. IARC monographs on the evaluation of carcinogenic risks to humans.
34
Yun, U. and B.W. Cho. 2004. Concentrations in VOCs in groundwater associated with land uses in Ulsan area. Econ. Environ. Geol. 37(6):613-629.
35
Yun, U., B.W. Cho, C.H. Eum, and I.H. Sung. 2003. Analysis on the contamination and source of VOCs in groundwaters of Gwangju area. Econ. Environ. Geol. 13(4):389-404.
Information
  • Publisher :Korean Society of Soil Science and Fertilizer
  • Publisher(Ko) :한국토양비료학회
  • Journal Title :Korean Journal of Soil Science and Fertilizer
  • Journal Title(Ko) :한국토양비료학회 학회지
  • Volume : 50
  • No :4
  • Pages :235-250
  • Received Date : 2017-06-23
  • Revised Date : 2017-08-24
  • Accepted Date : 2017-08-30
  • DOI :https://doi.org/10.7745/KJSSF.2017.50.4.235
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