• Status of Community Drinking Water in Korea and Implications for Appropriate Management
  • Lee, Jin-Yong;Park, Youngyun;Kim, Nam-Ju;Jeon, Woo-Hyun;
  • Department of Geology, College of Natural Sciences, Kangwon National University;Department of Geology, College of Natural Sciences, Kangwon National University;Department of Geology, College of Natural Sciences, Kangwon National University;Department of Geology, College of Natural Sciences, Kangwon National University;
Abstract
Community drinking water (CDW), mostly naturally flowing groundwater, plays important roles in supplying drinking water for urban and rural residents in Korea. Over 1,600 CDW facilities are distributed throughout the country, many of them situated in the outskirts of metropolitan cities. A large proportion of Korean people have become dependent on CDW for drinking due to a distrust of piped water's quality and a strong belief in the special medicinal effects of some CDWs. However, administrative and official management and the control of CDW facilities have been inadequate when compared with the strict examination and control of commercial bottled water, which is physically treated groundwater from deep bedrock aquifers. In this study, even though signs of anthropogenic contamination were not generally found, the tested chemical compositions of selected CDWs featured high enrichment of some constituents including Ca, Mg, Na, and HCO3 with natural origins such as water-rock interactions. Careless consumption of particular CDWs, which has no scientific basis, will not guarantee health improvement. Consequently, more intensive management of CDW facilities and a long-term interdisciplinary examination of the health effects of CDWs are needed to effectively protect people's health.

Keywords: Community drinking water;Yaksu (medical water);Carbonate;Iron;Anthropogenic contamination;

References
  • 1. Arno, K., Lindemann, J., Schellenberger, A., Beierkuhnlein, C., Kaupenjohann, M., and Peiffer, S., 1998, Slope deposits and water paths in a spring catchment, Frankenwald, Bavaria, Germany, Nutr. Cycling Agroecosyst., 50, 119-126.
  •  
  • 2. Avtar, R., Kumar, P., Surjan, A., Gupta, L.N., and Roychowdhury, K., 2013, Geochemical processes regulating groundwater chemistry with special reference to nitrate and fluoride enrichment in Chhatarpur area, Madhya Pradesh, India, Environ. Earth Sci. (in press).
  •  
  • 3. Baas Becking, L.G.M., Kaplan, I.R., and Moore, D., 1960, Limits of the natural environment in terms of pH and oxidationreduction potentials, J. Geol., 68, 243-284.
  •  
  • 4. Chae, G.T., Yun, S.T., Kim, K., and Mayer, B., 2006, Hydrogeochemistry of sodium-bicarbonate type bedrock groundwater in the Pocheon spa area, South Korea: water-rock interaction and hydrologic mixing, J. Hydrol., 321, 326-343.
  •  
  • 5. Choi, D.K., Woo, J., and Park, T.H., 2012, The Okcheon Supergroup in the Lake Chungju area, Korea: Neoproterozoic volcanic and glaciogenic sedimentary successions in a rift basin, Geosci. J., 16(3), 229-252.
  •  
  • 6. Choi, W.J., Han, G.H., Lee, S.M., Lee, G.T., Yoon, K.S., Choi, S.M., and Ro, H.M., 2007, Impact of land-use types on nitrate concentration and $\delta^{15}N$ in unconfined groundwater in rural areas of Korea, Agric. Ecosyst. Environ., 120, 259-268.
  •  
  • 7. GIMS (Ground Water Information Service), 2013, Use of water resources in Korea, http://www.gims.go.kr.
  •  
  • 8. Goncalves, T.D., Fischer, T., Grabe, A., Kolditz, O., and Weiss, H., 2013, Groundwater flow model of the Pipiripau watershed, Federal District of Brazil, Environ. Earth Sci., 69(2), 617-631.
  •  
  • 9. Hashimoto, S., Fujita, M., Furukawa, K., and Minami, J.I., 1987, Indices of drinking water concerned with taste and health, J. Ferment. Technol., 65, 185-192.
  •  
  • 10. Hem, J.D., 1985, Study and interpretation of the chemical characteristics of natural water, USGS, Alexandria, VA.
  •  
  • 11. Jalali, M., 2007, Salinization of groundwater in arid and semiarid zones: an example from Tajarak, western Iran, Environ. Geol., 52, 1133-1149.
  •  
  • 12. Jeelani, G., Bhat, N.A., and Shivanna, K., 2010, Use of 18O tracer to identify stream and spring origins of a mountainous catchment: A case study from Liddar watershed, Western Himalaya, India, J. Hydrol., 393(3-4), 257-264.
  •  
  • 13. Jeong, C.H. and Jeong, G.Y., 1999, Geochemical water quality and genesis of carbonated Dalki mineral water in the Chungsong area, Kyungpook, Econ. Environ. Geol., 32(5), 455-468 (in Korean with English abstract).
  •  
  • 14. Jeong, C.H., Kim, K.H., and Nagao, K., 2012, Hydrogeochemistry and origin of $CO_2$ and noble gases in the Dalki carbonate waters of the Chungson area, J. Eng. Geol., 22(1), 123-134 (in Korean with English abstract).
  •  
  • 15. Jeong, C.H., Park, C.H., and Lee, K.S., 2002, Water quality and hydrochemistry of natural springs and community wells in Daejeon area, Econ. Environ. Geol., 35(5), 395-406 (in Korean with English abstract).
  •  
  • 16. Jeong, C.H., Yoo, S.W., Kim, K.H., and Nagao, K., 2011, Hydrochemistry and origin of noble gases and $CO_2$ gas within carbonated mineral waters in the Kyeoungbuk-Kangwon Province, Korea, J. Eng. Geol., 21(1), 65-77 (in Korean with English abstract).
  •  
  • 17. Jung, I.W., Chang, H., and Bae, D.H., 2013, Spatially-explicit assessment of flood risk caused by climate change in South Korea, KSCE J. Civil Eng., 17(1), 233-243.
  •  
  • 18. Kaown, D., Koh, D.C., Mayer, B., and Lee, K.K., 2009, Identification of nitrate and sulfate sources in groundwater using dual stable isotope approaches for an agricultural area with different land use (Chuncheon, mid-eastern Korea), Agric. Ecosyst. Environ., 132, 223-231.
  •  
  • 19. Kim, C.S., Park, M.E., and Koh, Y.K., 2002, Isotopic, geochemical and hydrogeological studies on the mineral water in Korea: occurrence, origin and evolution, Korea Science Foundation (in Korean with English summary).
  •  
  • 20. Kim, H.S., Koo, D.S., and Park, Y.W., 1977, Mineral water investigation on 10 area in Seoul, J. Preven. Medic. Public Health, 10(1), 59-61 (in Korean with English abstract).
  •  
  • 21. Kim, I.S., Ha, H., Seo, W.S., Bae, J.S., Mun, H., Park, C.U., Oh, E.H., Lee, S.Y., and Kim, M.H., 1998, A study of water quality characteristic of natural mineral water in Chonnam area, Kor. J. Environ. Health Soc., 24(1), 87-97 (in Korean with English abstract).
  •  
  • 22. Kim, G.Y., Koh, Y.K., Bae, D.S., Kim, C.S., and Park, M.E., 2001, Geochemistry and isotope studies of the Shinchon $CO_2$-rich waters in the Gyeongsang Province, Econ. Environ. Geol., 34(1), 71-88 (in Korean with English abstract).
  •  
  • 23. Kim, K.A., Lee, B.O., Kim, O.M., Hur, M.J., Kim, K.T., Ro, J.I., Choe, C.S., Go, J.M., and Kim, Y.H., 2008, A study on pollution of spring in Incheon area, Incheon Metro. City Inst. Health Environ., 11, 152-167 (in Korean with English abstract).
  •  
  • 24. Kim, K.R., Gil, H.K., Lee, M.H., Eom, S.W., and Lee, J.Y., 2011, Survey of citizens public opinion for natural spring water in Seoul, J. Soil Groundwater Env., 16(2), 1-5 (in Korean with English abstract).
  •  
  • 25. KMA (Korea Meteorological Administration), 2013, Climate of Korea http://www.kma.go.kr/weather/climate/average_south.jsp.
  •  
  • 26. Ko, E.J., Kim, K.W., Kang, S.Y., Kim, S.D., Bang, S.B., Hamm, S.Y., and Kim, D.W., 2007, Monitoring of environmental phenolic endocrine disrupting compounds in treatment effluents and river waters, Korea, Talanta, 73(4), 674-683.
  •  
  • 27. Ko, Y.K., Kim, C.S., Choi, H.S., Park, M.E., and Bae, D.S., 2000, Geochemical studies of $CO_2$-rich mineral water in the Kangwon Province, J. Kor. Soc. Groundwater Environ., 7(2), 73-88 (in Korean with English abstract).
  •  
  • 28. Koh, Y.K., Kim, C.S., Choi, H.S., Park, M.E., and Bae, D.S., 2000, Geochemical studies of $CO_2$-rich mineral water in the Kangwon Province, J. Kor. Soc. Groundwater Environ., 7(2), 73-88 (in Korean with English abstract).
  •  
  • 29. Kumar, M., Ramanathan, A.L., Rao, M.S., and Kumar, B., 2006, Identification and evaluation of hydrogeochemical processes in the groundwater environment of Delhi, India, Environ. Geol., 50, 1025-1039.
  •  
  • 30. Kumar, S.K., Rammonhan, V., Sahayam, J.D., and Jeevanandam, M., 2009, Assessment of groundwater quality and hydrochemistry of Manimuktha River basin, Tamil Nadu, India, Environ. Monit. Assess., 159, 341-351.
  •  
  • 31. Lakshmanan, E., Kannan, R., and Kumar, M.S., 2003, Major ion chemistry and identification of hydrogeochemical processes of ground water in a part of Kancheepuram district, Tamil Nadu, India, Environ. Geosci., 10(4), 157-166.
  •  
  • 32. Lee, J.Y., 2013, Debate on healthy drinking water in Korea: Belief or science?, Environ. Sci. Europe (submitted).
  •  
  • 33. Lee, J.Y., Jeon, W.H., Park, Y., and Lim, H.G., 2012, Status and prospect of groundwater resources in Pyeongchang, Gangwondo, J. Geol. Soc. Korea, 48(5), 435-444 (in Korean with English abstract).
  •  
  • 34. Lee, J.Y. and Lee, K.K., 2000, Use of hydrologic time series data for identification of recharge mechanism in a fractured bedrock aquifer system, J. Hydrol., 229(3-4), 190-201.
  •  
  • 35. Lee, J.Y., Yi, M.J., Yoo, Y.K., Ahn, K.H., Kim, G.B., and Won, J.H., 2007, A review of the National Groundwater Monitoring Network in Korea, Hydrol. Process., 21, 907-919.
  •  
  • 36. Magesh, N.S. and Chandrasekar, N., 2013, Evaluation of spatial variations in groundwater quality by WQI and GIS technique: a case study of Virudunagar District, Tamil Nadu, India, Arab. J. Geosci., 6, 1883-1898.
  •  
  • 37. Moon, H. and Park, K.H., 1998, Mineral characteristics of spring water in Chonnam, Kor. J. Food Sci. Technol., 30(2), 253-259 (in Korean with English abstract).
  •  
  • 38. Moon, S.H., Hwang, J., Lee, J.Y., Hyun, S.P., Bae, B.K., and Park, Y., 2013, Establishing the origin of elevated uranium concentrations in groundwater near the central Ogcheon metamorphic belt, Korea, J. Environ. Qual., 42, 118-128.
  •  
  • 39. Park, Y., Lee, J.Y., Lim, H.G., and Park, Y.C., 2011a, Characteristics of hydraulic conductivity of carbonate aquifers in Gangwon province, J. Eng. Geol., 21(1), 79-85 (in Korean with English abstract).
  •  
  • 40. Park, Y.C., Jo, Y.J., and Lee, J.Y., 2011, Trends of groundwater data from the Korean National Groundwater Monitoring Stations: indication of any change?, Geosci. J., 15(1), 105-114.
  •  
  • 41. Rajmohan, N. and Elango, L., 2004, Identification and evolution of hydrogeochemical processes in the groundwater environment in an area of the Palar and Cheyyar River Basins, Southern India, Environ. Geol., 46, 47-61.
  •  
  • 42. Seo, K.H. and Ok, J., 2013, Assessing future changes in the East Asian summer monsoon using CMIP3 models: results from the best model ensemble, J. Clim., 26, 1807-1817.
  •  
  • 43. Sim, W.J., Lee, J.W., and Oh, J.E., 2010, Occurrence and fate of pharmaceuticals in wastewater treatment plants and rivers in Korea, Environ. Pollut., 158(5), 1938-1947.
  •  
  • 44. Singh, C.K., Kumari, R., Singh, R.P., Shashtri, S., Kamal, V., and Mukherjee, S., 2011, Geochemical modeling of high fluoride concentration in groundwater of Pokhran Area of Rajasthan, India, Bull. Environ. Contam. Toxicol., 86, 152-158.
  •  
  • 45. Srinivasamoorthy, K., Chidambaram, S., Prasanna, M.V., Vasanthavihar, M., Peter, J., and Anandhan, P., 2008, Identification of major sources controlling groundwater chemistry from a hard rock terrain-A case study from Mettur taluk, Salem district, Tamil Nadu, India, J. Earth Syst. Sci., 117(1), 49-58.
  •  
  • 46. Subba Rao, N. and Devadas, D.J., 2003, Fluoride incidence in groundwater in an area of Peninsular India, Environ. Geol., 45, 243-251.
  •  
  • 47. Tahmassebi, J.F., Duggal, M.S., Malik-Kotru, G., and Curzon, M.E.J., 2004, Soft drinks and dental health: A review of the current literature, J. Dent., 34, 2-11.
  •  
  • 48. Toran, L.E. and Saunders, J.A., 1999, Modeling alternative paths of chemical evolution of Na-HCO3-type groundwater near Oak Ridge, Tennessee, USA, Hydrogeol. J., 7, 355-364.
  •  
  • 49. Walton, N.R.G., 1989, Electrical conductivity and total dissolved solids-What is their precise relationship?, Desalination, 72(3), 275-292.
  •  
  • 50. Warren, J.J., Weber-Gasparoni, K., Marshall T.A., Drake, D.R., Dehkordi-Vakil, F., Dawson, D.V., and Tharp, K.M., 2009, A longitudinal study of dental caries risk among very young low SES children, Community Dent. Oral, 37(2), 116-122.
  •  
  • 51. WHO (World Health Organization), 2003, Total dissolved solids in drinking-water, WHO, Geneva.
  •  
  • 52. WHO, (World Health Organization), 2011, Guidelines for drinking-water quality, Fourth edition, WHO, Geneva.
  •  
  • 53. Williams, A.E., Lund, L.J., Johnson, J.A., and Kabala, Z.J., 1998, Natural and anthropogenic nitrate contamination of groundwater in a rural community, California, Environ. Sci. Technol., 32, 32-39.
  •  
  • 54. Yun, N.K. and Jeong, B.G., 1983, The investigation of medical water's quality on 9 areas in Taegu city and the suburb area, Med. J. Keimyung Univ., 2(2), 149-152 (in Korean with English abstract).
  •  

This Article

  • 2013; 18(6): 56-68

    Published on Nov 30, 2013

  • 10.7857/JSGE.2013.18.6.056
  • Received on Oct 11, 2013
  • Revised on Oct 15, 2013
  • Accepted on Oct 15, 2013