Browse > Article
http://dx.doi.org/10.5338/KJEA.2019.38.1.9

Stabilization of Arsenic in Paddy Soils Using Stabilizers  

Kang, Min Woo (Department of Environmental Engineering, College of Health Science, Yonsei University)
Oh, Sejin (Yeongheung Division, Korea South-East Power Co.)
Kim, Sung-Chul (Department of Bio-Environmental Chemistry, College of Agriculture and Life Sciences, Chungnam National University)
Lee, Sang Soo (Department of Environmental Engineering, College of Health Science, Yonsei University)
Publication Information
Korean Journal of Environmental Agriculture / v.38, no.1, 2019 , pp. 17-22 More about this Journal
Abstract
BACKGROUND: Soil contamination of As is a very sensitive environmental issue due to its adverse impact on human health and different characteristics with other heavy metals. With public awareness of As poisoning, there has been growing interest in developing guideline and remediation technologies for As-contaminated soil. The objective of this research was to evaluate the effectiveness of stabilizing amendments and soil dressing methods on the mobility of As in the contaminated rice paddy soils nearby mining area. METHODS AND RESULTS: Different amendments were mixed with surface and subsurface contaminated soils at a ratio of 3% (w/w) and monitored for five months. Three different extractants including 0.01M $CaCl_2$, TCLP, and PBET were used to examine As bioavailability in the soil and the concentration of As in rice grain was also measured with an inductively coupled plasma (ICP) spectroscopy. The results showed that all amendment treatments decreased As concentration compared to the control. Especially, coal mine drainage sludge (CMDS) treatment showed the highest efficiency of decreasing As concentration in the soil and rice grain. The values of Pearson correlation (r) between As concentrations in the soil and rice grain were 0.782, 0.753, and 0.678 for $CaCl_2$, TCLP, and PBET methods, respectively. Especially, $CaCl_2$ method was highly correlated between As concentrations of the soil and soil solution (r=0.719), followed by TCLP (r=0.706), PBET (r=0.561) methods. CONCLUSION: Stabilizing amendments can effectively reduce available As concentration in the soils as well as soil solution, and thereby potentially mitigating risks of crop contamination by As.
Keywords
Arsenic; Coal Mine Drainage Sludge; Rice Paddy Soil; Stabilization; Stabilizer;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Thornton, E. R. (1983). Applied environmental geochemistry, p. 64, Academic Press. London. UK.
2 Tsang, D. C., Olds, W. E., Weber, P. A., & Yip, A. C. (2013). Soil stabilisation using AMD sludge, compost and lignite: TCLP leachability and continuous acid leaching. Chemosphere, 93(11), 2839-2847.   DOI
3 Wagner, A., & Kaupenjohann, M. (2014). Suitability of biochars (pyro-and hydrochars) for metal immobilization on former sewage-field soils. European Journal of Soil Science, 65(1), 139-148.   DOI
4 Yang, J. E., Lee, K. W., Kim, J. J., & Lim, H. S. (1995). Changes of chemical species in soil solution induced by heavy metals. Korean Journal of Environmental Agriculture, 14(3), 263-271.
5 Yoo, K. Y., Ok, Y. S., & Yang, J. E. (2007). As (V) Immobilization in an aqueous solution by zerovalent iron under various environmental conditions. Korean Journal of Environmental Agriculture, 26(3), 197-203.   DOI
6 Bothe, J. V., & Brown, P. W. (1999). Arsenic immobilization by calcium arsenate formation. Environmental Science & Technology, 33(21), 3806-3811.   DOI
7 Yoon, I. H., Moon, D. H., Kim, K. W., Lee, K. Y., Lee, J. H., & Kim, M. G. (2010). Mechanism for the stabilization/solidification of arsenic contaminated soils with portland cement and cement kiln dust. Journal of Environmental Management, 91(11), 2322-2328.   DOI
8 Abd El-Azeem, S. A. M., Ahmad, M., Usman, A. R. A., Kim, K. R., Oh, S. E., Lee, S. S., & Ok, Y. S. (2013). Changes of biochemical properties and heavy metal bioavailability in soil treated with natural liming materials. Environmental Earth Sciences, 70(7), 3411-3420.   DOI
9 Almaroai, Y. A., Vithanage, M., Rajapaksha, A. U., Lee, S. S., Dou, X., Lee, Y. H., Sung, J. K., & Ok, Y. S. (2014). Natural and synthesised iron-rich amendments for As and Pb immobilisation in agricultural soil. Chemistry and Ecology, 30(3), 267-279.   DOI
10 Carbonell-Barrachina, A. A., Burlo, F., Valero, D., Lopez, E., Martinez-Romero, D., & Martinez-Sanchez, F. (1999). Arsenic toxicity and accumulation in turnip as affected by arsenic chemical speciation. Journal of Agricultural and Food Chemistry, 47(6), 2288-2294.   DOI
11 Cui, M., Jang, M., Cho, S. H., Khim, J., & Cannon, F. S. (2012). A continuous pilot-scale system using coalmine drainage sludge to treat acid mine drainage contaminated with high concentrations of Pb, Zn, and other heavy metals. Journal of Hazardous Materials, 215-216, 122-128.   DOI
12 Kim, J. H., Chung, D. Y., Oh, S. J., Kim, R. Y., Yang, J. E., Park, G. I., Lee, J. S., & Kim, S. C. (2012b). Determining soil quality of heavy metal contaminated agricultural field in Korea. Korean Journal of Soil Science and Fertilizer, 45(6), 1237-1241.   DOI
13 Duker, A. A., Garranza, E. J. M., & Hale, M. (2005). Arsenic geochemistry and health. Environment International, 31(5), 631-641.   DOI
14 Feng, M. H., Shan, X. Q., Zhang, S., & Wen, B. (2005). A comparison of the rhizosphere-based method with DTPA, EDTA, CaCl2, and NaNO3 extraction methods for prediction of bioavailability of metals in soil to barley. Environmental Pollution, 137(2), 231-240.   DOI
15 Kumpiene, J., Lagerkvist, A., & Maurice, C. (2008). Stabilization of As, Cr, Cu, Pb and Zn in soil using amendments-a review. Waste Management, 28(1), 215-225.   DOI
16 Kim, K. R., Owens, G., Naidu, R., & Kim, K. H. (2007). Assessment techniques of heavy metal bioavailability in soil. Korean Journal of Soil Science and Fertilizer, 40(4), 311-325.
17 Kim, M. S., Koo, N., Kim, J. G., Yang, J. E., Lee, J. S., & Bak, G. I. (2012a). Effects of soil amendments of Brassica campestris ssp. Chinensis Jusl. in heavy metalcontaminated soil. Korean Journal of Soil Science and Fertilizer, 45(6), 961-967.   DOI
18 Lee, W. C., Jeong, J. O., Kim, J. Y., & Kim, S. O. (2010). Characterization of arsenic immobilization in the Myungbong mine tailing. Economic and Environmental Geology, 43(2), 137-148.
19 Lee, S. H., Kim, E. Y., Park, H., Yun, J., & Kim, J. G. (2011). In situ stabilization of arsenic and metalcontaminated agricultural soil using industrial by-products. Geoderma, 161(1-2), 1-7.   DOI
20 Mandal, B. K., & Suzuki, K. T. (2002). Arsenic round the world: a review. Talanta, 58(1), 201-235.   DOI
21 Singh, T. S., & Pant, K. K. (2006). Solidification/stabilization of arsenic containing solid wastes using portland cement, fly ash and polymeric materials. Journal of Hazardous Materials, 131(1-3), 29-36.   DOI
22 Moon, D. H., Wazne, M., Yoon, I. H., & Grubb, D. G. (2008). Assessment of cement kiln dust (CKD) for stabilization/solidification (S/S) of arsenic contaminated soils. Journal of Hazardous Materials, 159(2-3), 512-518.   DOI
23 Oh, S. J., Kim, S. C., Yun, H. S., Kim, H. N., Kim, T. H., Yeon, K. H., Lee, J. S., Hong, S. J., & Yang, J. E. (2011). Evaluating heavy metal stabilization efficiency of chemical amendment in agricultural field. Korean Journal of Soil Science and Fertilizer, 44(6), 1052-1062.   DOI
24 Ok, Y. S., Kim, S. C., Kim, D. K., Skousen, J. G., Lee, J. S., Cheong, Y. W., Kim, S. J., & Yang, J. E. (2011). Ameliorants to immobilize Cd in rice paddy soils contaminated by abandoned metal mines in Korea. Environmental Geochemistry and Health, 33(1), 23-30.   DOI
25 Roman-Ross, G., Cuello, G. J., Turrillas, X., Fernandez-Martinez, A., & Charlet, L. (2006). Arsenite sorption and co-precipitation with calcite. Chemical Geology, 233(3-4), 328-336.   DOI
26 Shafiq, M., Iqbal, M. Z., & Mohammad, A. (2008). Effect of lead and cadmium on germination and seedling growth of Leucaena leucocephala. Journal of Applied Sciences and Environmental Management, 12(3), 61-66.