Korean Journal of Soil Science and Fertilizer (한국토양비료학회지)

Korean Society of Soil Science and Fertilizer (한국토양비료학회)
권호 표지
DOI QR코드

DOI QR Code

Establishment of Application Level for the Proper Use of Organic Materials as the Carbonaceous Amendments in the Greenhouse Soil

시설재배지 유기물자원 적정 시용기준 설정

  • Kang, Bo-Goo (Chungcheongbuk-do Agricultural Research and Extension Servies) ;
  • Lee, Sang-Young (Chungcheongbuk-do Agricultural Research and Extension Servies) ;
  • Lim, Sang-Cheol (Chungcheongbuk-do Agricultural Research and Extension Servies) ;
  • Kim, Young-Sang (Chungcheongbuk-do Agricultural Research and Extension Servies) ;
  • Hong, Soon-Dal (College of Agriculture, Life & Environment Science, Chungbuk National University) ;
  • Chung, Keun-Yook (College of Agriculture, Life & Environment Science, Chungbuk National University) ;
  • Chung, Doug-Young (College of Agriculture & Life Science, Chungnam National University)
  • Received : 2011.04.08
  • Accepted : 2011.04.14
  • Published : 2011.04.30
Download PDF
⟨ Previous Next ⟩

Abstract

For the environmental friendly soil management on the cultivation of crops in the greenhouse, organic materials, such as the by product-fertilizer derived from livestock manure, rice straw, mushroom media, rice hulls, wood sawdust, and cocopeat, were used as carbon sources adjusting the ratio of carbon to nitrogen to 10, 20, and 30 based on the inorganic soil N. In each C/N ratio of greenhouse soil, watermelon was cultivated in the greenhouse as crop for experiment for the spring and summer of the year and the experimental results were summarized as follows. The concentration of T-C in the organic materials applied were between $289{\sim}429g\;kg^{-1}$, In the C/N ratio of 10, using watermelon as the crop cultivated during the second half of the year in the greenhouse soil, the $NO_3$-N and EC were reduced by 21 to 37%, and 26 to 33%, respectively, except the by product-fertilizer from livestock manure, compared to the soil $NO_3$-N and EC used in the experiment. After the watermelon was cultivated in soils that C/N ratios were controlled as 10, 20, and 30 with wood sawdust adding as carbon sources in the three soils with the different EC values, EC values of the soils were reduced by 33, 42, and 39%, respectively, compared to the soil EC used in the experiment. The weight of watermelon was 10.1-13.4 kg per one unit, and, of the three soils with different EC values. In the soils with three different EC values controlled at C/N ratio of 20, the weight of watermelon was good. The degree of sugar of watermelon were 11.8 to 12.3 Brix, which means that the difference between the treatments was not significant. In conclusion, the C/N ratio of 20 controlled by the proper supply of organic materials according to the representative EC values shown in the greenhouse soils was optimal condition enough to maintain the soil management for the organic culture with the proper nutrient cycling.

시설재배 토양의 장기적인 물질순환적 친환경 토양관리를 위하여 유기물자원 (가축분부산물비료, 볏짚, 버섯배지, 팽연왕겨, 우드톱밥, 코코피트)을 토양의 무기태질소 대비 C/N율 10, 20, 30 조절량을 시용하는 처리를 두어 수박을 시험작물로 비닐하우스에서 2기작으로 재배하여 수행한 결과는 다음과 같다. 시용한 유기물자원의 T-C는 $289{\sim}429g\;kg^{-1}$이었으며, 유기물자원을 토양의 무기태질소 대비 C/N율 10 조절량을 시용하여 수박을 2기작 재배 후 토양의 질산태 질소는 시험전 토양에 비하여 가축분 부산물비료 처리를 제외 하고 21~37% 감소하였으며, 토양의 EC는 26~33% 경감효과가 있었다. 우드톱밥을 토양의 EC가 상이한 3개의 토양에 토양의 무기태질소 대비 C/N율을 10, 20, 30 조절 처리하여 수박을 재배한 결과 시험전 토양에 비하여 토양의 EC가 각각 33, 42, 39% 경감되었다. 수박의 과중은 개당 10.1~13.4 kg으로 토양의 EC가 낮은 토양I>토양II>토양III 순으로 수박의 과중이 높았으며 C/N 20 조절처리에서 3개의 토양은 양호한 경향이었다. 수박의 당도는 $11.8{\sim}12.3^{\circ}Brix$로 처리간에 차이는 없었으며 수박의 과실 특성상 상품에는 문제가 없었다. 탄소함량이 높은 유기물자원 공급으로 토양의 연작장해의 한 원인인 염류집적이 경감되어 품질과 수량성 증수을 기대할 수 있었다. 시설재배토양의 특성을 대표 할 수 있는 토양의 EC농도에 따라 유기물자원 시용시 토양의 무기태질소 대비 C/N 20 조절 시용기준을 적용하여도 물질순환적 유기재배의 토양관리에 문제가 없을 것으로 평가되었다.

Keywords

References

  1. Allison, F.E. 1966. The fate of nitrogen applied to soils. Adv. Agronomy 18:219-258. https://doi.org/10.1016/S0065-2113(08)60651-3
  2. Coleman, D.C., C.P.P. Reid, and C.Cole. 1983. Biological strategiess of nutrient cycling in soil system. Adv. Eco. Res. 13:1-55. https://doi.org/10.1016/S0065-2504(08)60107-5
  3. Duxbury, J.M., M.S. Smith, and J.W. Doran. 1989. Soil organic mater as source and a sink of plant nutrients. In Dynamic of Soil Organic Mater in Tropical Ecosystem. pp 33-68. University of Hawaii Press. Honolulu.
  4. Hwang, S.W., Y.S. Kim, B.R. Yeon, Y.J. Lee, and Y.D. Park. 1993. Effect of several metods of salt reduction on salt removal of soil in plastic film house. Paper of agrcultulal sciences in RDA, Korea. 35:276-280.
  5. Joh, K.R., C.S. Kang, A.S. Roh, J.M. Sim, and S.R Park. 2003. Effect of applicaton of organic materials on reduction of salt in plastic film house. Anual research report of Kung-gi Agricultural research and extension services. p. 463-473.
  6. Jung, B.G., G.B. Jung, and J.H. Yoon. 2003. Survey on the change of chemical properties of agricultural fields in Korea. p. 7-55 (In Proceeding of symposium on monitoring project on agri-environment quality in Korea. National Institue of Agricultural Science and Technology, Suwon, Korea).
  7. Kang, B.K. 1997. Chemical charateristics and salt movement of soil in green house area. Doctor Thesis. Chungbuk National University, Korea.
  8. Kang, B.G,, I.M. Jeong, J.J. Kim, S.D. Hong, and K.B. Min. 1997. Chemical characteristics of plastic film house soils in Chungbuk area. Korean J. Soil Sci. Fert. 30:265-271.
  9. Kang, C.S., A.S. Roh, T.J. Won, and S.E. Lee. 2006. Effect of application of easily decomposable carbon on reducing of soil salinization. Anual research report of Kung-gi Agricultural research and extension services. p. 409-420.
  10. Kim, J.G., C.H. Lee, J.G. Joh, and Y.H. Lee. 1996. Subsoil inverting depth and fertilizer needs in salt accumulated soils of plastic film house. Rural Development Administration J. Agri. Sci. (Soil & Fert.). 38:370-375.
  11. Kim, J.G., G.J. Jeong, S.J. Kang, and J.M. Jeong. 2000. Effect of application of organic mater on chemical charateristics of soil and quality of cucumber. Anual research report of Jeon-nam Agricultural research and extension services. p. 249-258.
  12. Kim, L.Y., H.J. Cho, B.K. Hyun, and W.P. Park. 2001. Effects of physical improvement practices at plastic film house soil. Korean J. Soil Sci. Fert. 34:2-97.
  13. KOSIS (Korean Statistical Information Service). 2010. Agriculture statistical database
  14. Kwak, H.K., K.S Seong, N.J. Lee, S.B. Lee, M.S. Han, and K.A. Roh. 2003. Changes in chemical properties and fauna of plastic film house soil by application of chemical fertilizer and composted pig manure. Korean J. Soil Sci. Fert. 36:304-310.
  15. Kwon, J.B., J.R Kwon, Y.S. Shin, C.R. Kim, and B.S. Choi. 1996. Effect of organic matters on horticultural characteristics and yield of potato (Solanum tuberosum L.) in greenhouse. Korean J.Hort. Sci. 37:137-145.
  16. Lee, Y., S.C. Kim, and Y.H. Park. 2002. Development of nutrient balance indiccator. p. 282-296. In Research report of agro-environment research. National Institute of Agricultrual Science and Technology, Suwon, Korea.
  17. Lee, Y.H., S.G. Kim, S.H. Shin, J.H. Choi, Y.J. Lee, and H.M. Kim. 2006. Investigation of the utilization of organic materials and the chemical properties of soil in the organic farms in korea. Korea J. Organic Agriculture. 14:55-67.
  18. NIAST (National Institute of Agricultural Science and Technology). 2000. Analytical methods of soil and plant. NIAST, Suwon, Korea.
  19. RDA (Rural Development and Administration). 2008. Anual report of the monitoring project on agricultural environment quality. p. 11.
  20. Roh, A.S., K.R. Joh, T.J. Won, and S.E. Lee. 2005. Effect of long term application of organic mater on reducing of soil salinization. Anual research report of Kung-gi Agricultural research and extension services. p. 485-496.
  21. Seo, Y.H. 2001. Improvement on the grrenhouse soil. Anual research report of Kang-won Agricultural research and extension services. p. 719-720.
  22. Shin, J.H. 2007. Determine appropriate rate of organic matter application according to the soil condition of organic farming. In research report of NIAST, Suwon, Korea.
  23. Shin, Y.K., Y.H. Lee, K.N. Hwang, and K.S. Lee. 1992. Effect of application of organic mater on horticultural crops. p. 239-243. In Research report of agro-environment research. NIAST, Suwon, Korea.
  24. Song, Y.S., H.K. Kwak, B.L. Hur, and S.E. Lee. 1996. Use efficiency of nitrogen accumulated in plastic film house soils under continuous vegetable cultivation. Korea J. Soc. Soil Sci. Fert. 29:347-352.
  25. Uhm, M.J., S.G. Han, K.C. Chel, Y.H. Moon, and J.S. Choi. 2001. Properities of plastic film house soils and physiological disorder of eggplant. Korean J. Soil Sci. Fert. 34:192-198.
  26. Won, T.J., K.R. Joh, C.S. Kang, A.S. Roh. 2007. Evaluation on effect of application of organic culture materials on reducing of soil salinization. Anual research report of Kung-gi Agricultural research and extension services. p. 514-527.
  27. Yoon, J.H., L.Y. Kim, P.K. Jung, J.S. Suh, and H.J. Jun. 2002. Development of soil quality indicators. p. 240-258. In Research report of agro-environment research. National Institute of Agricultrual Science and Technology, Suwon, Korea.

Cited by

  1. Effects of reduced additional fertilizer on tomato yield and nutrient contents in salt accumulated soil vol.42, pp.4, 2015, https://doi.org/10.7744/cnujas.2015.42.4.423
  2. Soil Physico-chemical Properties of Organic Grapes Farms with Different Culture Facilities and Soil Management Practices vol.46, pp.5, 2013, https://doi.org/10.7745/KJSSF.2013.46.5.399
  3. Chemical Properties of Paddy Soils and Factors Affecting Their Change in Jeonnam Province vol.48, pp.5, 2015, https://doi.org/10.7745/KJSSF.2015.48.5.492