Effect of Swine Bone Powder for Reduce Cadmium Uptake by Rice
Abstract
The effect of swine bone powder application on bioavailability of Cd in contaminated soil from Tak Province, Thailand were conducted. The bioavailability of Cd was investigated in term of the uptake by rice plant (Oryza sativa L.) in green house at three different application rates of swine bone powder amended soil, including 5, 10 and 15%, respectively. The result demonstrated that the efficiency of cadmium uptake in Khao Dawk Mali 105 rice were in range 0.18-0.20 % and the 5% swine bone amended soil had a positive effect on promoting plant growth and seed yield. Cd concentration in both of shoot and roots decreased with increasing the swine bone application rates. Cadmium bioaccumulation in plant root to soil and translocation factor from root to shoot was less than one. The results indicated that swine bone powder-amended soil could be an alternative and cost-effective method to support plant growth and decrease Cd mobility in soil.
References
[1] Chen, S.B., Zhu, Y., Ma, Y. and Mckay, G. 2006. Effect of bone char application on Pb bioavailability in a Pb-contaminated soil. Environmental Pollution, 139: 433-439.
[2] Cheney, R.L. 2010. Cadmium and Zinc. In P. Hooda (Ed.), Trace Elements in Soils. UK: Blackwell publishing Ltd.
[3] Cheung, C.W., Chan, C.K., Porter, J.F. and Mckay, G. 2001. Film-Pore Diffusion Control for the Batch Sorption of Cadmium Ions from Effluent onto bone char. Journal of Colloid and Interface Science, 243: 328-336.
[4] Dabbi, S., Azzi, M. and Guardia, M. 1999. Removal of hexavalent chromium from wastewaters by bone charcoal. Fresenius’ Journal of Analytical Chemistry, 363: 404-407.
[5] Danny, C.K.K., et al. 2004. Sorption equilibria of metal ions on bone char. Gemosphere, 54: 273-281.
[6] Gabadon, C., Marzal, P., Ferrer, J. and Seco, A. 1996. Single and competitive adsorption of Cd and Zn onto a granular activated carbon. Water Research, 30: 3050-3060.
[7] Huang, Y.Z. et al. 2006. Effects of bone char on uptake and accumulation of heavy metals by three rice genotypes (Oryza sativa L.). Journal of Agro-Environmental Science, 25 (6): 1481–1486.
[8] Kassio Ferreira Mendes et al. 2019. Cow bone char as a sorbent to increase sorption and decrease mobility of hexazinone, metribuzin, and quinclorac in soil. Geoderma, 343: 40-49.
[9] Kołodynska D., et al. 2012. Kinetic and adsorptive characterization of biochar in metal ions removal. Chemical Engineering Journal, 197: 295-305.
[10] Lin, A.J., Zhang, X.H., and Su., Y.H. 2007. Chemical fixation of metals in soil using bone char and assessment of soil genotoxicity. Environmental Science, 28: 232-237.
[11] Ma, L.Q. and Rao, G.N., 1997. Effects of phosphate rock on sequentialchemical extraction of lead in contaminated soils. Journal of Environmental Quality, 26: 788-794.
[12] Ma, L.Q., Logan, T.J. and Traina, S.J. 1995. Lead immobilization fromaqueous solutions and contaminated soils using phosphate rocks. Environmental Science and Technology, 29: 1118-1126.
[13] Nadia Glæsner et al. 2019. Crystalline apatite in bone char produced at low temperature ameliorates phosphorus-deficient soils. Chemosphere, 223: 723-730.
[14] Okeola, F. O. and Odebunmi, E.O. 2001. Comparison of freundlich and Langmuir isotherm for adsorption of methylene blue by agrowaste derived activated carbon. Advances in Environmental Biology, 4(3): 329-335.
[15] Park, J. H., et al. 2011. Biochar reduces the bioavailability and phytotoxicity of heavy metals. Plant and Soil, 438: 439-451.
[16] Quevauviller, P., et al. 1998. Certified reference material for the quality of EDTA and DTPA-extractable trace metal contents in calcareous soil (CRM 600). Fresenius’ Journal of Analytical Chemistry, 360: 505-511.
[17] Sneddon, I.R., Garelick, H. and Valsami-Jones, E. 2005. An investigation into arsenic (V) removal from aqueous solutions by hydroxylapatite and bonechar. Mineralogical Magazine, 69: 769-780.
[18] Tangjuank S., Insuk N., Tontrakoon J. and Udeye V. 2009. Adsorption of lead (II) and cadmium (II) ions from aqueous solutions by adsorption on activated carbon prepared from cashew nutshell. World Academy of science, Engineering and Technology, 52: 110-16.
[19] Thongdeelert, T. 2012. “Itai-Itai desease in contamination area of Japan.” Available at: http://wqm.pcd.go.th/km/images/stories/agriculture/2555/itaiitai.pdf (in Thai)
[20] Trakal, L. et al. 2011. Biochar application to metal-contaminated sol: evaluating of Cd, Cu, Pb and Zn sorption behavior using single and multi-element sorption experiment.” Plant, soil and Environment, 57: 372-380.
[21] Wilson, J.A., Demis, J., Pulford, L.D. and Thomas, S. 2001. Sorption of cr (III) and Cr (VI) by natural (bone) charcoal. Environmental Geochemistry and Health, 23: 291-295.
[22] Zwoniter, J.C., Pierzynski, G.P. and Hettiarachchi, G.M., 2003. Effects of phosphorus additions on lead, cadmium and zinc bioavailability in a metal-contaminated soil. Water, Air, and soil Pollution, 143: 193-209.
[23] Department of Primary Industries and mines. Cadmium contamination in Environment Amphur Maesot, Tak Province. Available at: http://www.dpim.go.th/laws/article?catid=122&articleid=309
[24] Office of the Royal Development Projects Boards. 2012. The planting of Oryza sativa L. var Khao Dawk Mali 105. Movement Gen Tree Publishing.
[25] Pollution Control Department. 2004. Summary of Environmental Samplings in Mae Sot after cadmium contamination. Bangkok: Ministry of Natural Resources and Environment, Thailand. (in Thai)
[26] United State Environmental Protection Egency. 1996. Method 3050B acid Digestion of Sediments, Sludges, and Soils: Revision 2. Available at: http://www/epa/gov/osw/harzard/testmethods/sw846/pdfs/3050.pdf
[2] Cheney, R.L. 2010. Cadmium and Zinc. In P. Hooda (Ed.), Trace Elements in Soils. UK: Blackwell publishing Ltd.
[3] Cheung, C.W., Chan, C.K., Porter, J.F. and Mckay, G. 2001. Film-Pore Diffusion Control for the Batch Sorption of Cadmium Ions from Effluent onto bone char. Journal of Colloid and Interface Science, 243: 328-336.
[4] Dabbi, S., Azzi, M. and Guardia, M. 1999. Removal of hexavalent chromium from wastewaters by bone charcoal. Fresenius’ Journal of Analytical Chemistry, 363: 404-407.
[5] Danny, C.K.K., et al. 2004. Sorption equilibria of metal ions on bone char. Gemosphere, 54: 273-281.
[6] Gabadon, C., Marzal, P., Ferrer, J. and Seco, A. 1996. Single and competitive adsorption of Cd and Zn onto a granular activated carbon. Water Research, 30: 3050-3060.
[7] Huang, Y.Z. et al. 2006. Effects of bone char on uptake and accumulation of heavy metals by three rice genotypes (Oryza sativa L.). Journal of Agro-Environmental Science, 25 (6): 1481–1486.
[8] Kassio Ferreira Mendes et al. 2019. Cow bone char as a sorbent to increase sorption and decrease mobility of hexazinone, metribuzin, and quinclorac in soil. Geoderma, 343: 40-49.
[9] Kołodynska D., et al. 2012. Kinetic and adsorptive characterization of biochar in metal ions removal. Chemical Engineering Journal, 197: 295-305.
[10] Lin, A.J., Zhang, X.H., and Su., Y.H. 2007. Chemical fixation of metals in soil using bone char and assessment of soil genotoxicity. Environmental Science, 28: 232-237.
[11] Ma, L.Q. and Rao, G.N., 1997. Effects of phosphate rock on sequentialchemical extraction of lead in contaminated soils. Journal of Environmental Quality, 26: 788-794.
[12] Ma, L.Q., Logan, T.J. and Traina, S.J. 1995. Lead immobilization fromaqueous solutions and contaminated soils using phosphate rocks. Environmental Science and Technology, 29: 1118-1126.
[13] Nadia Glæsner et al. 2019. Crystalline apatite in bone char produced at low temperature ameliorates phosphorus-deficient soils. Chemosphere, 223: 723-730.
[14] Okeola, F. O. and Odebunmi, E.O. 2001. Comparison of freundlich and Langmuir isotherm for adsorption of methylene blue by agrowaste derived activated carbon. Advances in Environmental Biology, 4(3): 329-335.
[15] Park, J. H., et al. 2011. Biochar reduces the bioavailability and phytotoxicity of heavy metals. Plant and Soil, 438: 439-451.
[16] Quevauviller, P., et al. 1998. Certified reference material for the quality of EDTA and DTPA-extractable trace metal contents in calcareous soil (CRM 600). Fresenius’ Journal of Analytical Chemistry, 360: 505-511.
[17] Sneddon, I.R., Garelick, H. and Valsami-Jones, E. 2005. An investigation into arsenic (V) removal from aqueous solutions by hydroxylapatite and bonechar. Mineralogical Magazine, 69: 769-780.
[18] Tangjuank S., Insuk N., Tontrakoon J. and Udeye V. 2009. Adsorption of lead (II) and cadmium (II) ions from aqueous solutions by adsorption on activated carbon prepared from cashew nutshell. World Academy of science, Engineering and Technology, 52: 110-16.
[19] Thongdeelert, T. 2012. “Itai-Itai desease in contamination area of Japan.” Available at: http://wqm.pcd.go.th/km/images/stories/agriculture/2555/itaiitai.pdf (in Thai)
[20] Trakal, L. et al. 2011. Biochar application to metal-contaminated sol: evaluating of Cd, Cu, Pb and Zn sorption behavior using single and multi-element sorption experiment.” Plant, soil and Environment, 57: 372-380.
[21] Wilson, J.A., Demis, J., Pulford, L.D. and Thomas, S. 2001. Sorption of cr (III) and Cr (VI) by natural (bone) charcoal. Environmental Geochemistry and Health, 23: 291-295.
[22] Zwoniter, J.C., Pierzynski, G.P. and Hettiarachchi, G.M., 2003. Effects of phosphorus additions on lead, cadmium and zinc bioavailability in a metal-contaminated soil. Water, Air, and soil Pollution, 143: 193-209.
[23] Department of Primary Industries and mines. Cadmium contamination in Environment Amphur Maesot, Tak Province. Available at: http://www.dpim.go.th/laws/article?catid=122&articleid=309
[24] Office of the Royal Development Projects Boards. 2012. The planting of Oryza sativa L. var Khao Dawk Mali 105. Movement Gen Tree Publishing.
[25] Pollution Control Department. 2004. Summary of Environmental Samplings in Mae Sot after cadmium contamination. Bangkok: Ministry of Natural Resources and Environment, Thailand. (in Thai)
[26] United State Environmental Protection Egency. 1996. Method 3050B acid Digestion of Sediments, Sludges, and Soils: Revision 2. Available at: http://www/epa/gov/osw/harzard/testmethods/sw846/pdfs/3050.pdf
Published
2020-06-16
How to Cite
PECHRSAN, Sasithorn; SRISATIT, Thares.
Effect of Swine Bone Powder for Reduce Cadmium Uptake by Rice.
Journal of Environmental Management and Tourism, [S.l.], v. 11, n. 3, p. 721-727, june 2020.
ISSN 2068-7729.
Available at: <https://journals.aserspublishing.eu/jemt/article/view/5056>. Date accessed: 26 apr. 2024.
doi: https://doi.org/10.14505//jemt.v11.3(43).26.
Section
Article
Copyright© 2023 The Author(s). Published by ASERS Publishing 2023. This is an open access article distributed under the terms of CC-BY 4.0 license.