한국농공학회논문집 (Journal of The Korean Society of Agricultural Engineers)

  • 제63권1호
  • /
  • Pages.89-102
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  • 2021
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  • 1738-3692(pISSN)
  • /
  • 2093-7709(eISSN)
한국농공학회 (The Korean Society of Agricultural Engineers)
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저수구역 경작지 토양의 유기물 및 영양염류 용출특성 분석

Analysis of Organic Matter and Nutrient Leaching Characteristics of Agricultural Land Soils in Reservoir Area

  • 투고 : 2020.10.12
  • 심사 : 2020.12.15
  • 발행 : 2021.01.31
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초록

Soils in agricultural lands contain large amount of organic matter and nutrients due to the injected fertilizers and manure. During heavy rain, surface water and base runoff pollutants flows into a nearby stream or lake with eroded soil from agricultural lands. On the other hands, agricultural lands near the lake are inundated due to the increase of the water level in the lake, leading to organic matter and nutrient release from the inundated soil. In this study, releasing rates of nutrient salts and organic substances were analyzed for the soil in the agricultural land, where cultivation activities has been carried out and periodically flooded, to account for the possibility of contamination from the inundated agricultural land in reservoir areas The experiment results have shown that COD was released from the soil in anaerobic conditions, and T-P was released in both anaerobic and aerobic conditions. However, in the case of T-N, it was found that the runoff by soil was not made before the rainfall occurred, and when the soil was impound due to rainfall, the elution occurred under the aerobic conditions. Through the results of this study, it was possible to account for the effect of flooded agricultural lands on the water quality in the lake, and this could be reflected in an efficient agricultural non-point pollution management policy. In order to determine the precise releasing rate for each agricultural land, it is believed that the leaching experiment for paddy fields and grasslands are needed.

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참고문헌

  1. Cho, Y. C., and S. W. Chung, 2007. Sediment release rate of nutrients from namyang reservoir. Journal of Korean Society of Environmental Engineers 29(12): 1345-1352 (in Korean).
  2. Huh, J. Y., and J. K. Park, 2009. A Survey on effects of environment-friendly farming in the flood control area of a dam reservoir on water pollution. 2009 Korean Society of Civil Engineers of Academin Conference 3491-3494 (in Korean).
  3. Jarv ie, H. P., A. N. Sharpley, P. J. Withers, J. T. Scott, B. E. Haggard, and C. Neal, 2013. Phosphorus mitigation to control river eutrophication: Murky waters, inconvenient truths, and 'postnormal' science. Journal of Environmental Quality 42(2): 295-304. https://doi.org/10.2134/jeq2012.0085
  4. Ki, B. M., B. M. Lim, E. H. Na, and J. H. Choi, 2010. A study on the nutrient release characteristics from sediments in the asan reservior. Journal of Korean Society of Environmental Engineers 32(1): 1-8 (in Korean).
  5. Ribaudo, M., J. Delgado, L. Hansen, M. Livingston, R. Mosheim, and J. Williamson, 2011. Nitrogen In Agricultural Systems: Implications For Conservation Policy. USDA Economi. Research Report NO. 127
  6. Su, X., H. Wang, and Y. Zhang, 2013. Health risk assessment of nitrate contamination in groundwater: A case study of an agricultural area in Northeast China. Water resources management: 3025-3034.
  7. Ministry of Environment, 2017. Water pollution process test standards.
  8. Ministry of Environment, 2018. Annual report on the occurrence and response of algee (water bloom) in 2017.