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http://dx.doi.org/10.7857/JSGE.2021.26.6.018

Soil Loss Reduction and Stabilization of Arsenic Contaminated Soil in Sloped Farmland using CMDS (Coal Mine Drainage Sludge) under Rainfall Simulation  

Koh, Il-Ha (National Environment Lab. (NeLab))
Kwon, Yo Seb (National Environment Lab. (NeLab))
Jeong, Mun-Ho (Technology Research & Development Institute, Korea Mine Rehabilitation and Mineral Resources Corp.)
Ji, Won Hyun (Department of General Education for Human Creativity, Hoseo University)
Publication Information
Journal of Soil and Groundwater Environment / v.26, no.6, 2021 , pp. 18-26 More about this Journal
Abstract
Soil aggregation begins with flocculation of clay particles triggered by interfacial reactions of polyvalent cation such as Ca2+ and Fe3+, and they are also known as important elements to control the mobility of arsenic in soil environment. The objective of this study was to investigate the feasibility of CMDS (coal mine drainage sludge) for soil loss reduction and stabilization of arsenic-contaminated soil in a 37% sloped farmland under rainfall simulation. The amount of soil loss decreased by 43% when CMDS was applied, and this result was not significantly different from the case of limestone application, which yielded 46% decrease of soil loss. However, the relative amount of dispersed clay particles in the sediment CMDS-applied soil was 10% lower than that of limestone-applied soil, suggesting CMDS is more effective than limestone in inducing soil aggregation. The concentrations of bioavailable arsenic in CMDS amended soil decreased by 46%~78%, which was lower than the amount in limestone amended soil. Therefore, CMDS can be used as an effective amendment material to reduce soil loss and stabilize arsenic in sloped farmland areas.
Keywords
Soil loss; Sloped farmland; CMDS (coal mine drainage sludge); Arsenic; Stabilization;
Citations & Related Records
Times Cited By KSCI : 4  (Citation Analysis)
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1 KME(Korea Ministry of Environment), 2001, A Study on the Conservation of Surface Soil and Erosion Control.
2 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, Korea, p.232.
3 Kim, M.S., Min, H.G., Lee, B.J., Chang, S.I., Kim, J.G., Koo, N.I., Park, J.S., and Park, G.I., 2014, The applicability of the acid mine drainage sludge in the heavy metal stabilization in soils, Korean J Environ Agric., 33(2), 78-85.   DOI
4 Koh, I.H., Roh, H., Hwang, W.J., Seo, H.G., and Ji, W.H., 2018, Reducing soil loss of sloped land using lime-organic compost mixtures under rainfall simulation, J. Soil Groundwater Environ., 23(3), 43-50.   DOI
5 Kumpiene, J., Lagerkvist, A., and Maurice, C., 2008, Stabilization of As, Cr, Cu, Pb and Zn in soil using amendments - a review, Waste Manage., 28(1), 215-225.   DOI
6 Bothe, J.V. and Brown, P.W., 1999, Arsenic immobilization by calcium arsenate formation, Environ. Sci. Technol., 33(21), 3806-3811.   DOI
7 Koh, I.H., Yu, C., Park, M.J., and Ji, W.H., 2019, Reduction of soil loss from sloped agricultural field by using hydrated lime, J. Soil Groundwater Environ., 24(2), 1-7.   DOI
8 Brady, N.C. and Weil, R.R., 2014, Elements of the Nature and Properties of Soils, Pearson Education Limited.
9 Koh, I.H., Kang, H.C., Kwon, Y.S., Yu, C., Jeong, M.H., and Ji, W.H., 2020, Reduction of soil loss from sloped agricultural field by using organic compost, J. Soil Groundwater Environ., 25(4), 48-57.   DOI
10 Mehlich, A., 1984, Mehlich 3 soil test extractant: a modification of Mehlich 2 extractant, Commun. in Soil Sci. Plant Anal., 15(12), 1409-1416.   DOI
11 Ko, M.S., Kim, J.Y., Bang, S.B., Lee, J.S., Ko, J.I., and Kim, K.W., 2010, An investigation of arsenic stabilization in contaminated soil in the vicinity of abandoned mine using various soil additives, J. Korean Soc. Geosystem Eng., 47(6), 834-843.
12 Kwon, H.H. and Nam, G.S., 2013, Mine Reclamation Engineering, DongHwa Technology Publing Co.
13 Lee, G.J., Lee, J.T., Ryu, J.S., Oh, D.S., and Kim, J.S., 2012, Effects of slope gradient and rainfall intensity on soil losses with rainfall simulator experiment, Korean J. Soil Sci. Fert., 45(6), 877-881.   DOI
14 Lee, J.R., Kim, J.J., Cho, J.D., Hwang, J.Y., and Lee, M.H., 2011, Feasibility study of the stabilization for the arsenic contaminated farmland soil by using amendments at Samkwang abandoned mine, Econ. Environ. Geol., 44(3), 217-228.   DOI
15 Lee, M.H. and Jeon, J.H., 2010, Study for the stabilization of arsenic in the farmland soil by using steel making slag and limestone, Econ. Environ. Geol., 43(4), 305-314.
16 Moon, D.H., Cheong, K.H., Koutsospyros, A., Chang, Y.Y., Hyun, S.H., Ok, Y.S., and Park, J.H., 2016, Assessment of waste oyster shells and coal mine drainage sludge for the stabilization of As-, Pb-, and Cu-contaminated soil, Environ. Sci. Pollut. Res., 23, 2362-2370.   DOI
17 NAAS (National Academy of Agricultural Science), 2010, Methods of soil chemical analysis.
18 NIER (National Institute of Environmental Research), 2018, Korea standard methods for soil analysis.
19 Son, J.H., Roh, H., Lee, S.Y., Kim, S.K., Kim, G.H., Park, J.K., Yang, J.K., and Chang, Y.Y., 2009, Stabilization of heavy metal contaminated paddy soils near abandoned mine with steel slag and CaO., J. Soil Groundwater Environ., 14(6), 78-86.
20 Lee, G.Y, Cui, M., Yoon, Y.M., Khim, J.H., Jang, M., 2018, Passive treatment of arsenic and heavy metals contaminated circumneutral mine drainage using granular polyurethane impregnated by coal mine drainage sludge, J. Clean Prod., 186, 282-292.   DOI
21 Yang, J.E., Jung, J.B., Kim, J.E., and Lee,G.S., 2008, Ag-Environmental Science, CIR.
22 NIER (National Institute of Environmental Research), 2019, Korea standard methods for water analysis.
23 Cho, S.J., Park, C.S., Um, D.I., 2010, Soil Science, Hyangmunsa.
24 Zhu, X., Qi, X., Wang, H., Shi, Y., Liao, T., Li, Y., Liu, C., and Wang, X., 2014, Characterization of high-arsenic sludge in copper metallurgy plant, In: J.S. Carpenter, C. Bai, J.Y. Hwang, S. Ikhmayies, B. Li, S.N. Monteiro, Z. Peng, and M. Zhang(ed), Characterization of Minerals, Metals, and Materials 2014, John Wiley & Sons, Inc., p.173-184.
25 Choi, Y.B., Lim, J.E., Jung, Y.S., Lee, S.S., and Ok, Y.S., 2012, Best management practices for sloping upland erosion control: Feasibility of PAM and biopolymer application, J Agri Life Environ Sci., 24(2), 30-39.
26 Eu, S., Li, Q., Lee, E.J., and Im, S.J., 2015, Predicting surface runoff and soil erosion from an unpaved forest road using rainfall simulation, J. Korean Env. Res. Tech., 18(3), 13-22.
27 Evanko, C.R. and Dzombak, D.A., 1997, Remediation of Metals-Contaminated Soils and Groundwater, GWRTAC Technology Evaluation Report.
28 Chae, J.C., Park, S.J., Kang, B.H., and Kim, S.H., 2013, Principles of Crop Cultivation, Hyangmunsa.
29 Choi, Y.B., Choi, B.S., Kim, S.W., Lee, S.S., and Ok, Y.S., 2010, Effects of polyacrylamide and biopolymer on soil erosion and crop productivity in sloping uplands: A field experiment, Journal of KSEE, 32(11), 1024-1029.
30 Choi, B.S., Lim, J.E., Choi, Y.B., Lim, K.J., Choi, J.D., Joo, J.H., Yang, J.E., and Ok, Y.S., 2009, Applicability of PAM(Polyacrylamide) in soil erosion prevention: rainfall simulation experiments, Korean J. Environ. Agric., 28(3), 249-257.   DOI
31 Dong, J., Zhang, K., and Guo, Z., 2012, Runoff and soil erosion from highway construction spoil deposits: a rainfall simulation study, TRANSPORT RES D, 17(1), 8-14.   DOI
32 Liu, S., Wen, K., Armwood, C., Bu, C., Li, C., Amini, F., and Li, L., 2019, Enhancement of MICP-treated sandy soils against environmental deterioration, J. Mater. Civ. Eng., 31(12).
33 Gonzaga, M.I.S., Ma, L.Q., Pacheco, E.P., and Santos, W.M., 2012, Predicting arsenic bioavailability to hyperaccumulator Pteris Vittata in arsenic-contaminated soils, Int. J. Phytoremediat, 14, 939-949.   DOI
34 Chung, H.Y., Kim, S.H., and Nam, K.P., 2021, Application of microbially induced calcite precipitation to prevent soil loss by rainfall: Effect of particle size and organic matter content, J Soil Sediment, 21, 2744-2754.   DOI
35 Moon, D.H., Dermtas, D., and Menounou, N., 2004, Arsenic immobilization by calcium-arsenic precipitates in lime treated soils, Sci. Total Environ., 330(1-3), 171-185.   DOI
36 NIAST (National Institute of Agricultural Science and Technology), 2000, Methods for soil and plant analysis.
37 Pierzynski, G.M., Sims, J.T., and Vance, G.F., 1994, Soils and Environmental Quality, CRC Press, Inc., Boca Raton, Ann Arbor, London, Tokyo.
38 Yang, J.S., Kim, Y.S., Park, S.M., and Baek, KT., 2014, Removal of As(III) and As(V) using iron-rich sludge produced from coal mine drainage treatment plant, Environ. Sci. Pollut. Res., 21, 10878-10889.   DOI
39 Moon, D.H., Cheong, K.H., Kim, T.S., Khim, J.Y., Choi, S.B., Moon, O.R., and Ok, Y.S., 2009, Stabilization of As in soil contaminated with chromated copper arsenate (CCA) using calcinated oyster shells, Korean J. Environ. Agric., 28(4), 378-385.   DOI