Korean Journal of Environmental Agriculture (한국환경농학회지)

The Korean Society of Environmental Agriculture (한국환경농학회)
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Assessment of Nitrogen Impaction on Watershed by Rice Cultivation

벼농사에서 질소유출이 수질에 미치는 영향평가

  • Roh, Kee-An (National Institute of Agricultural Science and Technology, RDA) ;
  • Kim, Min-Kyeong (National Institute of Agricultural Science and Technology, RDA) ;
  • Lee, Byeong-Mo ;
  • Lee, Nam-Jong (National Institute of Agricultural Science and Technology, RDA) ;
  • Seo, Myung-Chul (National Institute of Agricultural Science and Technology, RDA) ;
  • Koh, Mun-Hwan (National Institute of Agricultural Science and Technology, RDA)
  • 노기안 (농업과학기술원 환경생태과) ;
  • 김민경 (농업과학기술원 환경생태과) ;
  • 이병모 (농업과학기술원 친환경농업과) ;
  • 이남종 (농업과학기술원 환경생태과) ;
  • 서명철 (농업과학기술원 환경생태과) ;
  • 고문환 (농업과학기술원 환경생태과)
  • Published : 2005.09.30
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Abstract

It is important to understand and evaluate the environmental impacts of rice cultivation for developing environmentally-friendly agriculture because rice is main crop in Korea and rice cultivation have both functions of water pollution and purification with environmental and cultivation conditions. This paper presents the evaluation of nitrogen impact by rice cultivation on water system. A simple protocol was proposed to assess the potential amount of nitrogen outflow from paddy field and most of parameters affect on the nitrogen outflow from paddy field such as the amount of fertilizer application, water balance, the quality and quantity of irrigation water, soil properties, nitrogen turnover in the soil and cultivation method were considered. To develop the protocol, coefficients for parameters affected nitrogen turnover and outflow were gotten and summarized by comparison and analysis of all possible references related, and by additional experiments at field and laboratory. And potential amount of nitrogen input and output by water in paddy field were estimated with the protocol at the conditions of the nitrogen contents of irrigation water, amount of fertilizer application, and irrigation methods. Where irrigation water was clean, below 1.0 mg $L^{-1}$ of nitrogen concentration, rice cultivation polluted nearby watershed. At the conditions of 2.0 mg $L^{-1}$ of nitrogen concentration, 110 kg $ha^{-1}$ of nitrogen fertilizer application and flooding irrigation, rice cultivation had water pollution function, but it had water purification function with intermittent irrigation. At the conditions of 3.0 mg $L^{-1}$ of nitrogen concentration and 110 kg $ha^{-1}$ of nitrogen fertilizer application, rice cultivation had water purification function, but that had water pollution function with 120 kg $ha^{-1}$ of nitrogen application. Where irrigation water was polluted over 6.0 mg $L^{-1}$ of nitrogen, it was evaluated that rice cultivation had water purifying effect, even though the amount of nitrogen application was 120 kg $ha^{-1}$.

벼농사에 의한 질소가 하천수질에 미치는 영향을 종합적으로 평가하기 위해 공급 질소의 유입량과 유출 및 이용되는 양은 동일하다는 질소 balance 개념 평가기법을 개발하였다. 유입량과 유출량 결정에 영향을 주는 시비량, 관개수 수질, 관개량과 물이용 수지, 토양유기물 함량, 토양질소공급량, 유기물 시용여부, 이앙방법, 물관리 방법, 수확량, 암모니아 휘산 및 탈질량, 토양잔류량 등 관련요인들과 요인상호간의 관계를 자료 분석, 현지포장 및 실내실험을 통해 지수화하였으며 사용된 지수들을 종합하여 벼농사의 수질영향평가법으로 제시하였다. 질소의 총 공급량에서 대기유출, 작물이용, 토양 잔류 부분을 제외한 차이를 벼농사에서 질소의 잠재유출량으로 산정하여 벼농사가 수질에 미치는 영향으로 평가하였으며, 개발된 방법으로 평가한 우리나라의 평균적인 환경 및 재배 조건에서 벼농사는 수계를 통한 질소의 유입량과 유출량이 거의 균형을 이루어 주변수질에 큰 영향을 미치지 않는 것으로 평가되었다. 하지만 관개수중의 질소농도가 1.0 mg $L^{-1}$ 이하로 깨끗한 지역에서의 벼농사는 수질의 오염원으로 작용하였으며, 관개수중의 질소농도가 2.0 mg $L^{-1}$이고 시비량이 110 kg $ha^{-1}$인 조건에서는 간단관개를 할 경우는 벼농사는 수질을 정화하는 기능이 있었으나 반대로 상시담수를 할 경우는 오염원으로 작용하였다. 질소농도가 3.0 mg $L^{-1}$인 경우는 시비량 110 kg $ha^{-1}$의 조건에서는 벼농사는 수질정화의 기능이 있었지만 시비량이 120 kg $ha^{-1}$로 증가하면 오염원으로 작용하였으며, 관개수중의 질소농도가 6.0 mg $L^{-1}$ 이상으로 비교적 오염된 지역에서는 시비량 120 kg $ha^{-1}$ 까지도 벼농사는 수질을 정화하는 기능을 가지고 있는 것으로 평가되었다. 하지만 이 같은 평가 방법은 앞으로도 지속적인 자료보완과, 요인분석의 세분화를 통해 더욱 정밀한 평가가 가능하도록 추가적인 연구가 추진되어야 할 것으로 사료된다.

Keywords

References

  1. Koyama, T, Sybuya. M., Tokuyasu, M., Shimomura, T, Ide, T, and Ide, K. (1977) Balance sheet and residual effects of fertilizer nitrogen in Saga paddy field. Proc. Int. Seminar on SEFMIA Tokyo(20), 289-296
  2. Kolenbrander, G. J. (1981) Leaching of nitrogen in agriculture. In nitrogen losses and surface run-off. (ed. Brogan, J. C.) Nijhoff. 199-216
  3. Maeda K I. (1983) Quantitative estimation of behavior of nitrogen applied to paddy field. Bull. Natl. Agric. Res. Cent.(1), 121-192
  4. Yoon, K. S. (1999) Study on the mechanism of organic matter turnover for modelling of pollution load estimation from paddy field. Annual research report of Chonnan university. 6-35
  5. Seo, M. C., Kang, K. K., Yun, H. B., and Eom, K. C. (2001) Assesment of positive function of paddy farming according to agricultural production conditions, Annual research report of agricultural environment. NIAST. 355-387
  6. Lim, J. N. and Oho, J. S. (1970) Survey of infiltration rate at main soil series of paddy field. Annual research report of NIAST. 2, 88-90
  7. Shin, C. S., Mun, J., Kim, J. G., and Kim, J. D. (1971) Survey of infiltration rate at main soil series of paddy field. Annual research report of NIAST. 2, 117-123
  8. Oho, J. S. and Ryu, K. S. (1972) Survey of infiltration rate at main soil series of paddy field. Annual research report of RDA. 218-235
  9. Roh, K. A. and Ha, H. S. (1999) Nutrient balance during rice cultivation in sandy soil affected by the fertilizer management. J. Korean Soc. Soil Sci. Fert. 32(2), 155-163
  10. Kazumi, K. A message from Japan and Asia to the world water discussion (3rd World water Forum report). Japanese Institute of Irrigation and Drainage. 41
  11. Lee, K. C., Koo, J. W., and Goh, H. S. (1983) Study on the evapotranspiration requirement in paddy fields(I). Research report of Jeonbuk university. 14, 129-133
  12. Goh H. S. (1984) Study on the evapotranspiration requirement in paddy fields (II). Research report of Jeonbuk university. 15, 133-138
  13. Mizuta, K. (2001) N, P and K input by irrigation water into paddy field of Fukuoka prefecture. Jpn. J. Crop Sci. 70(4), 595-598 https://doi.org/10.1626/jcs.70.595
  14. Oho, D. S., Eom, K. C., and Shin, J.. S. (1994) Development of water saving technology for rice cultivation. Annual research report of agricultural environment. NIAST. 172
  15. Lee, J. S., Kim, B. Y., Kim, J. H, and Hong, S. G. (1999) Chemical composition of rainwater in Suwon and Ansung area. Kor. J. of Environ. Agric. 18(2), 169-173
  16. Lee, J. S., Jung, G. B., Kim, J. H, Kim, W. I., Yun, S. G., and 1m, J. C. (2001) Volume-weighted ion concentration of rainwater in Taean area. Kor. J. of Environ. Agric. 20(4), 284-288
  17. Lee, J. S., Kim, J. H., Jung, G. B., and Eom, K. C. (2003) Volume-weighted ion concentration of rainwater in Suwon area during farming season. Korean J. of Agriculture and Forest Meteorology, 5(1), 1-5
  18. Tisdale S. L., Waner, L. N., and Beaton, J. D. (1985) Soil fertility and fertilizer (4th edition). 125
  19. Ito, J. and Iimura, K. (1989) Amount of crude organic matter in fine grey paddy soil in Hokuriku district and its effect on nitrogen mineralization. Jpn. J. Soil Sci. and Plant Nutr. 60(1), 56-59
  20. Kiyoichi K. (1981) Chemistry of soil organic matter, second edition. Society publish center (japanese), 199-202
  21. NlAST. (1999) Fertilizer application recommendation for crops. National Institute of Agricultural Science and Technology, Suwon, Korea
  22. Tasima, F., Tatsumoto, T., and Egashira, K. (2003) Nitrogen balance in the paddy field of the aigamapaddy cultivation. Jpn. J. Soil Sci Plant Nutr, 74, 15-21
  23. Toriyama K. (1996) Progress and prospect of the research on paddy soil management under various rice growing system 1. progress in nutrient behavior and management research on paddy soil(l) nitrogen. Jpn. J. Soil Sci. Plant Nutr. 67(2), 198-207
  24. Kim, Y. H., Yoon, J. H., and Jung, B. K. (2000) Nitrogen suppling capacity of paddy soil. Annual research report of agricultural environment. NlAST. 244-266
  25. Yeon B. Y. (1998) Changes of rice yield and soil properties by continuous application of chemical fertilizer and soil amendments. Annual research report of agricultural environment. NIAST. 451-460
  26. Roh, K. A., Kim, P. J., Kang, K. K., Ahn, Y. S., and Yun, S. H (1999) Reduction of nutrient infiltration by supplement of organic matter in paddy soil. Kor. J. of Environ. Agric. 18(3), 196-203
  27. Patrie, W. H. Jr. and Ready, K. R. (1997) Fertilizer nitrogen reactions in flooded soils. Proc. Int. Seminar on SEFMlA. Tokyo. 275-281
  28. Park, Y. H., Lee, Y., Kim, S. C., Roh, J. S., Park, K. R., and Lee, J. Y. (2004) Integrated nutrient management for rice cultivation. Annual research report of agricultural environment. NIAST. 404-429
  29. Yatazawa M. (1978) Agro-ecosystem in Japan. In : Cycling of mineral nutrients in agricultural ecosystem. Elsevier Scientific Pub. Co., Amsterdam. 167-179
  30. Hasegawa K. (1992) Studies on the behavior and balance of nitrogen in paddy field near the lake and its influence of environment especially on water quality. Annual report of Shiga prefecture agriculture experiment station 17, 1-164
  31. Lee, Y., Park, Y. H, and Kim, S. C. (2004) Research . on gaseous nitrogen losses from agricultural soil. Annual research report of agricultural environment. NIAST. 477-487
  32. Jung Y. S., Ha, S. K., Cho, B. O., and Lee, H. J. (1996) Use of phosphate coated urea to decrease ammonia volatilization loss from direct seeded rice field at early stage. J. Korean Soc. Soil Sci. Fert. 29(1), 8-14
  33. Takei Y. and Uehara., Y. (1973) Nitrification and denitrification in the surface layer of submerged soil (part 1). Jpn. J. Soil Sci. and Plant Nutr. 44, 463-470
  34. Shoji, S., Wada, G., Saito, K., Shinbo, I., and Takahashi, J. (1971) The fate of fertilizer nitrogen applied to the paddy field and its absorption by rice plant. II. The fate of basal nitrogen in paddy field. ipn. J. Crop Sci. 40, 281-286 https://doi.org/10.1626/jcs.40.281
  35. Wada, G., Shoji, S., Takahashi, J., Saito, K., and Shinbo, I. (1971) The fate of fertilizer nitrogen applied to the paddy field and its absorption by rice plant. III. The fate of top-dressed nitrogen in the soil and its absorption by rice plant. Jpn. J. Crop Sci. 40, 287-293 https://doi.org/10.1626/jcs.40.287
  36. Lee, S. E., Song, Y. S., Lee, Y. J., and Lee, C. S. (1993) Change of nitrate concentration in soil with application of rice straw and the amount of chemical fertilizer. Annual research report of agricultural environment. NIAST. 31
  37. Shibara H., Kawamura, M., and Kobayashi, M. (1994) Effect of rice straw application on the quality of infiltration water and soil micro-organism at paddy field. Annual report of Shiga prefecture experimental station. 35, 1-18
  38. Yoo, C. H., Kim, J. G., Park, K. H., and Kim, S. J. (1988) Effect of long-term organic matter application on physico-chemical properties in rice paddy soil 2. The effect of some physical properties of paddy field by the long-term application of rice straw and compost. J. Kor Soc. Soil Sci. fert. 21(4), 373-379
  39. RDA. (1999) Annual report of the monitoring on agro-environmental quality. 9
  40. RDA. (2003) Annual report of the monitoring on agroenvironmental quality. 40

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