• Reducing Soil Loss of Sloped Land using Lime-Organic Compost mixtures under Rainfall Simulation
  • Koh, Il-Ha;Roh, Hoon;Hwang, Wonjae;Seo, Hyunggi;Ji, Won Hyun;
  • National Environment Lab. (NeLab);National Environment Lab. (NeLab);Department of Environmental Science and Ecological Engineering, Korea University;National Environment Lab. (NeLab);Mine Reclamation Corporation (MIRECO);
  • 인공강우 모사를 통한 석회/유기퇴비 혼합물의 경사지 토양유실 억제효과
  • 고일하;노훈;황원재;서형기;지원현;
  • 환경기술정책연구원;환경기술정책연구원;고려대학교 환경생태공학부;환경기술정책연구원;한국광해관리공단;
Abstract
In a previous study, the feasibility of four materials (bentonite, steelmaking slag, lime and organic compost) to induce soil aggregate formation was assessed and the mixtures of organic compost and lime were chosen as most effective amendments in terms of cost benefit. This work is a subsequent study to evaluate the effectiveness of those amendments in reducing soil loss in $15^{\circ}$ sloped agricultural area by using rainfall simulation test. Three different soils were treated with two conditions of organic compost/lime mixtures (2% + 2%, 3% + 1%, w/w). In the amended soils, soil fertility was increased due to the increase of CEC, T-N, and T-P. During the rainfall simulation, suspended solid in run-off water from amended soil were reduced by 43% ~ 78%. When the content of organic compost was higher than that of lime, reduction of soil loss was also increased by 67% ~ 78%. Sediment discharge was also decreased by 72% ~ 96% in the amended soil. Similar to the suspended solid analysis, higher organic compost content led to more reduction of soil discharging, which implies organic compost is more effective than lime in reducing soil loss. The overall result suggests that the mixtures of organic compost and lime could be used as amendment materials to reduce soil loss in sloped farmland.

Keywords: Soil loss;Sloped land;Lime;Organic compost;Run-off water;

References
  • 1. Brady, N.C. and Weil, R.R., 2014, Elements of the Nature and Properties of Soils, Pearson Education Limited.
  •  
  • 2. Cho, S.J., Park, C.S., and Um, D.I., 2002, Soil Science, Hyangmunsa.
  •  
  • 3. Hur, S.O., Jung, K.H., Ha, S.K., Kwak, H.K., and Kim, J.G., 2005, Mathematical description of soil loss by runoff at inclined upland of maize cultivation, Korean J. Soil Sci. Fert., 38(2), 66-71.
  •  
  • 4. Hwang, W.J., Bang, H.W., Hyun, S.H., Ji, W.H., and Lee., S.H., 2016, Assessment of several amendments for soil erosion reduction in sloping land, Proceedings of KoSSGE 2016 fall conference, Daejeon, Koea, p.232.
  •  
  • 5. Jung, K.H., Hur, S.O., Ha, S.G., Park, C.W., and Lee, H.H., 2007, Runoff pattern in upland soils with various soil texture and slope at torrential rainfall events, Korean J. Soil Sci. Fert., 40(3), 208-213.
  •  
  • 6. Kim, G.H., Kim, K.Y., Kim, J.G., Sa, D.M., Seo, J.S., Son, B.G., Yang, J.E., Eom, K.C., Lee, S.E., Jeong, G.Y., Jeong, D.Y., Jeong, Y.T., Jeong, J.B., and Hyun, H.N., 2009, Soil Science, Hyangmunsa.
  •  
  • 7. Kim, G.R., Park, J.S., Kim, M.S., Gu, N.I., Lee, S.H., Lee, J.S., Kim, S.C., Yang, J.E., and Kim, J.G., 2010, Changes in heavy metal phytoavailability by application of immobilizing agents and soil cover in the upland soil nearby abandoned mining area and subsequent metal uptake by red pepper, Korean J. Soil Sci. Fert., 43(6), 864-871.
  •  
  • 8. Kim, J.Y., Davis, A.P., and Kim, K.W., 2003, Stabilization of available arsenic in highly contaminated mine tailings using iron, Environ. Sci. Technol,. 37, 189-195.
  •  
  • 9. KME (Korea Ministry of Environment), 2001, A Study on the Conservation of Surface Soil and Erosion Control.
  •  
  • 10. KME (Korea Ministry of Environment), 2006, Research Project for Optimal Management of Non-point Pollution Source in Highland Farm Areas.
  •  
  • 11. KME (Korea Ministry of Environment), 2016, Korea standard methods for water analysis.
  •  
  • 12. Lee, H.H., Ha, S.K., Hur, S.O., Jung, K.H., Kim, W.T., and Kim, K.H., 2006, Characteristics of soil water runoff and percolation in sloped land with different soil textures, Korean J. Soil Sci. Fert., 39(5), 268-273.
  •  
  • 13. NAAS (National Academy of Agricultural Science), 2010, Methods of soil chemical analysis.
  •  
  • 14. Osborn, B., 1954, Effectiveness of cover in reducing soil splash by raindrop impact, J SOIL WATER CONSERV, 9, 70-76.
  •  
  • 15. Sparks, D.L., 1995, Environmental Soil Chemistry, Academic Press, San Diego, New York, Boston, London, Sydney, Tokyo, Toronto.
  •  
  • 16. Wainwright, J., Parsons, A.J., and Abrahams, A.D., 2000, Plotscale studies of vegetation, overland flow and erosion interactions: case studies from Arizona and New Mexico, Hydrol. Process, 14, 2921-2943.
  •  
  • 17. Yang, J.E., Jung, J.B., Kim, J.E., and Lee,G.S., 2008, Ag-Environmental Science, CIR.
  •  

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