Abstract
South Korea is located in the Asian monsoon region, and paddy rice farming is one of the important agricultural activities, which may contribute to the non-point source pollution of inland water bodies along with rainfall runoff. The status of water quality in rural streams located throughout South Korea was examined in this study by water quality monitoring and statistical analysis. Totally six surveys were conducted in 2003 and 2005 to monitor 300 streams located in rural subwatersheds; these streams are affected by agricultural activities and water supply for agricultural practices. The monitoring was performed at the terminal point of each subwatershed. In each study year, the streams were monitored in the three hydrological periods (April, July, and October) to observe differences in the impacts of agricultural activity and rainfall pattern. During the surveys, 15 water quality parameters were measured and interpreted using multivariate statistical methods including factor analysis and cluster analysis. Results show that the water quality of the rural streams monitored in this study appeared to meet the Korean water quality criteria for agricultural use, which are 8.0 and 100 mg/L for biochemical oxygen demand and suspended solids, respectively. In terms of organic contamination and suspended solids, the best stream water quality was observed in October compared to other periods. This can be attributed to the fact that October follows the rice-harvesting period and has low rainfall; thus the streams are probably less affected by agricultural activities and surface runoff. The three hydrological periods did not show much variation in the nitrogen and phosphorus parameters related to stream water nutrient conditions. Factor analysis indicates that the first five factors for April explained about 67% of the total sample variance. In July, the first four factors explained about 60% of the total variance, while the first four factors for October explained about 65%. Cluster analysis reveals that the streams could be divided into four groups in April and October and five groups in July. The box-and-whisker plots of the physicochemical variables indicate that Group A had the best water quality among the groups. This study demonstrates that the rural stream water quality of South Korea in the Asian monsoon region can be greatly affected by agricultural activities such as paddy rice farming and rainfall patterns.
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References
Andrade JM, Parada D, Muniategui S, González E, Alonso E (1992) Multivariate analysis of environmental data for two hydrographic basins. Anal Lett 25:379–399
APHA (1995) Standard methods for the examination of water and wastewater, 19th edn. American Public Health Association, Washington, DC
Aruga R, Negro G, Ostacoli G (1993) Multivariate data analysis applied to the investigation of river pollution. Fresenius J Anal Chem 346:968–975
Bodo BA (1992) Statistical analyses of regional surface water quality in southeastern Ontario. Environ Monit Assess 23:165–187
Briz-Kishore BH, Murali G (1992) Factor analysis for revealing hydrochemical characteristics of a watershed. Environ Geol Water Sci 19:3–9
Christophersen N, Hooper RP (1992) Multivariate analysis of stream water chemical data: the use of principal components analysis for the end-member mixing problem. Water Resour Res 28:99–107
Evans CD, Davies TD, Wigington PJ, Tranter M, Kretser WA (1996) Use of factor analysis to investigate processes controlling the chemical composition of four streams in the Adirondack Mountains, New York. J Hydrol 185:297–316
Gang SA, An GK (2006) Spatio-temporal variation analysis of physico-chemical water quality in the Yeongsan-River watershed. Korean J Limnology 39:73–84
Grimalt JO, Olivé J, Gomez-Belinchon JI (1990) Assessment of organic source contributions in coastal waters by principal component and factor analysis of the dissolved and particulate hydrocarbons and fatty acid contents. Int J Environ Anal Chem 38:305–320
Haag I, Westrich B (2002) Processes governing river water quality identified by principal component analysis. Hydrol Process 16:3113–3130
Helena B, Pardo R, Vega M, Barrado E, Fernández JM, Fernández L (2000) Temporal evolution of groundwater composition in an alluvial aquifer (Pisuerga River, Spain) by principal component analysis. Water Res 34:807–816
Kim JH, Kim RH, Lee J, Cheong TJ, Yum BW, Chang HW (2005) Multivariate statistical analysis to identify the major factors governing groundwater quality in the coastal area of Kimje, South Korea. Hydrol Process 19:1261–1276
Lambrakis N, Antonakos A, Panagopoulos G (2004) The use of multicomponent statistical analysis in hydrogeological environmental research. Water Res 38:1862–1872
Lee JY, Cheon JY, Lee KK, Lee SY, Lee MH (2001) Statistical evaluation of geochemical parameter distribution in a ground water system contaminated with petroleum hydrocarbons. J Environ Qual 30:1548–1563
Møhlenberg F, Petersen S, Petersen AH, Gameiro C (2007) Long-term trends and short-term variability of water quality in Skive Fjord, Denmark—nutrient load and mussels are the primary pressures and drives that influence water quality. Environ Monit Assess 127:503–521
Morin G, Fortin JP, Sochanska W, Lardeau JP (1979) Use of principal components analysis to identify homogeneous precipitation stations for optimal interpolation. Water Resour Res 15:1841–1850
Muñoz-Carpena R, Ritter A, Li YC (2005) Dynamic factor analysis of groundwater quality trends in an agricultural area adjacent to Everglades National Park. J Contam Hydrol 80:49–70
Papatheodorou G, Lambrakis N, Panagopoulos G (2007) Application of multivariate statistical procedures to the hydrochemical study of a coastal aquifer: an example from Crete, Greece. Hydrol Process 21:1482–1495
Petersen W, Bertino L, Callies U, Zorita E (2001) Process identification by principal components analysis of river water-quality data. Ecol Model 138:193–213
Reid JM, MacLeod DA, Cresser MS (1981) Factors affecting the chemistry of precipitation and river water in an upland catchment. J Hydrol 50:129–145
Seyhan E, van de Griend AA, Engclen GB (1985) Multivariate analysis and interpretation of the hydrochemistry of a dolomite reef aquifer, northern Italy. Water Resour Res 21:1010–1024
Suk H, Lee KK (1999) Characterization of a ground water hydrochemical system through multivariate analysis: clustering into ground water zones. Ground Water 37:358–366
Uhm MJ, Choi JS, Han SG, Kim KC, Moon YH (2000) Irrigation water qualities along Dong-Jin river watershed during 1994–1998. Korean J Environ Agric 19(2):110–115
Vega M, Pardo R, Barrado E, Debán L (1998) Assessment of seasonal and polluting effects on the quality of river water by exploratory data analysis. Water Res 32:3581–3592
Zhou F, Liu Y, Guo H (2007) Application of multivariate statistical methods to water quality assessment of the watercourses in northwestern New Territories, Hong Kong. Environ Monit Assess 132:1–13
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Kim, JH., Choi, CM., Kim, SB. et al. Water quality monitoring and multivariate statistical analysis for rural streams in South Korea. Paddy Water Environ 7, 197–208 (2009). https://doi.org/10.1007/s10333-009-0162-1
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DOI: https://doi.org/10.1007/s10333-009-0162-1