The Pattern of Heavy Metals Distribution in Time Chronosequence of Ex-Tin Mining Ponds in Bangka Regency, Indonesia
Andri Kurniawan(1*), Oedjijono Oedjijono(2), Tamad Tamad(3), Uyi Sulaeman(4)
(1) Department of Aquaculture, University of Bangka Belitung, Jl. Balunijuk, Merawang, Bangka, Bangka Belitung 33172, Indonesia
(2) Faculty of Biology, Jenderal Soedirman University, Jl. Dr. Suparno no. 63, Karang Bawang, Grendeng, Purwokerto 53122, Central Java, Indonesia
(3) Department of Agriculture, Jenderal Soedirman University, Jl. Dr. Suparno no. 61, Karang Bawang, Grendeng, Purwokerto 53122, Central Java, Indonesia
(4) Department of Chemistry, Faculty of Science and Technology, Jenderal Soedirman University, Jl. Dr. Suparno no. 61, Karang Bawang, Grendeng, Purwokerto 53122, Central Java, Indonesia
(*) Corresponding Author
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[1] de Silva, A.A.L., de Carvalho, M.A.R., de Souza, S.A.L., Dias, P.M.T., Filho, R.G.S., Saramago, C.S.M., Bento, C.A.M., and Hofer, E., 2012, Heavy metal tolerance (Cr, Ag and Hg) in bacteria isolated from sewage, Braz. J. Microbiol., 43 (4), 1620–1631.
[2] Guan, Y., Shao, C., and Ju, M., 2014, Heavy metal contamination assessment and partition for industrial and mining gathering areas, Int. J. Environ. Res. Public Health, 11 (7), 7286–7303.
[3] Kurniawan, A., 2017, Chronosequence effect of post tin mining ponds to metals residu and microecosystem change, Omni-Akuatika, 13 (1), 60–65.
[4] Ashraf, M.A., Maah, M.J., and Yusoff, I., 2012, Speciation of heavy metals in the sediments of former tin mining catchment, Iran. J. Sci. Technol. Trans. A Sci., 36 (2), 163–180.
[5] Daniel, V.N., Chudusu, E.S., Chup, J.A., and Pius, N.D., 2014, Variations of heavy metals in agricultural soils irrigated with tin water in Heipang District of Barkin Ladi, Plateau State, Nigeria, Int. J. Sci. Technol., 3 (5), 255–263.
[6] Ashraf, M.A., Maah, M.J., and Yusoff, I., 2012, Morphology, geology and water quality assessment of former tin mining catchment, Sci. World J., 2012, 369206.
[7] Urbanová, M., Kopecký, J., Valášková, V., Ságová-Marečková, M., Elhottová, D., Kyselková, M., Moënne-Loccoz, Y., and Baldrian, P., 2011, Development of bacterial community during spontaneous succession on spoil heaps after brown coal mining, FEMS Microbiol. Ecol., 78 (1), 59–69.
[8] Kurniawan, A., 2016, Microorganism communities response of ecological changes in post tin mining ponds, RRJoMV, 6 (1), 17–26.
[9] Violante, A., Cozzolino, V., Perelomov, L., Caporale, A.G., and Pigna, M., 2010, Mobility and bioavailability of heavy metals and metalloids in soil environments, J. Soil Sci. Plant Nutr., 10 (3), 268–292.
[10] Akcil, A., and Koldas, S., 2006, Acid mine drainage (AMD): causes, treatment and case studies, J. Cleaner Prod., 14 (12-13), 1139–1145.
[11] Tan, G.L., Shu, W.S., Hallberg, K.B., Li, F., Lan, C.Y., and Huang, L.N., 2007, Cultivation-dependent and cultivation-independent characterization of the microbial community in acid mine drainage associated with acidic Pb/Zn mine tailings at Lechang, Guangdong, China, FEMS Microbiol. Ecol., 59 (1), 118–126.
[12] Campaner, V.P., Luiz-Silva, W., and Machado, W., 2014, Geochemistry of acid mine drainage from a coal mining area and processes controlling metal attenuation in stream waters, Southern Brazil, An. Acad. Bras. Ciênc., 86 (2), 539–554.
[13] Bardgett, R.D., Bowman, W.D., Kaufmann, R., and Schmidt, S.K., 2005, A temporal approach to linking aboveground and belowground ecology, Trends Ecol. Evol., 20 (11), 634–641.
[14] Ahmad, A.K., and Al-Mahaqeri, S.A., 2015, Human health risk assessment of heavy metals in fish species collected from catchments of former tin mining, Int. J. Res. Stud. Sci. Eng. Technol., 2 (4), 9–21.
[15] Zeng, F., Ali, S., Zhang, H., Ouyang, Y., Qiu, B., Wu, F., and Zhang, G., 2011, The influence of pH and organic matter content in paddy soil on heavy metal availability and their uptake by rice plants, Environ. Pollut., 159 (1), 84–91.
[16] Huang, L.N., Tang, F.Z., Song, Y.S., Wan, C.Y., Wang, S.L., Liu, W.Q., and Shu, W.S., 2010, Biodiversity, abundance, and activity of nitrogen-fixing bacteria during primary succession on a copper mine tailings, FEMS Microbiol. Ecol., 78 (3), 439–450.
[17] Abdel-Raouf, N., Al-Homaidan, A.A., and Ibraheem, I.B.M., 2012, Microalgae and wastewater treatment, Saudi J. Biol. Sci., 19 (3), 257–275.
[18] Tscherko, D., Hammesfahr, U., Zeltner, G., Kandeler, E., and Böcker, R., 2005, Plant succession and rhizosphere microbial communities in a recently deglaciated alpine terrain, Basic Appl. Ecol., 6 (4), 367–383.
[19] Fierer, N., Nemergut, D., Knight, R., and Craine, J.M., 2010, Changes through time: Integrating microorganisms into the study of succession, Res. Microbiol., 161 (8), 635–642.
[20] Quirós, R., 2003, The relationship between nitrate and ammonia concentrations in the pelagic zone of lakes, Limnetica, 22 (1-2), 37–50.
[21] Michalski, R., and Kurzyca, I., 2006, Determination of nitrogen species (nitrate, nitrite and ammonia ions) in environmental samples by ion chromatography, Pol. J. Environ. Stud., 15 (1), 5–18.
[22] Mihale, M.J., 2015, Nitrogen and phosphorus dynamics in the waters of the Great Ruaha River, Tanzania, J. Water Resour. Ocean Sci., 4 (5), 59–71.
[23] Akan, J.C., Audu, S.I., Mohammed, Z., and Ogugbuaja, V.O., 2013, Assessment of heavy metals, pH, organic matter and organic carbon in roadside soils in Makurdi Metropolis, Benue State, Nigeria, J. Environ. Prot., 4 (6), 618–628.
[24] Kuriata-Potasznik, A., Szymczyk, S., Skwierawski, A., Glińska-Lewczuk, K., and Cymes, I., 2016, Heavy metal contamination in the surface layer of bottom sediments in a flow-through lake: A case study of Lake Symsar in Northern Poland, Water, 8 (8), 358.
[25] Maher, W., Krikowa, F., Wruck, D., Louie, H., Nguyen, T., and Huang, W.Y., 2002, Determination of total phosphorus and nitrogen in turbid waters by oxidation with alkaline potassium peroxodisulfate and low pressure microwave digestion, autoclave heating or the use of closed vessels in a hot water bath: Comparison with Kjeldahl digestion, Anal. Chim. Acta, 463 (2), 283–293.
[26] Song, Y., Hahn, H.H., and Hoffmann, E., 2002, Effects of solution conditions on the precipitation of phosphate for recovery a thermodynamic evaluation, Chemosphere, 48 (10), 1029–1034.
[27] Kumar, M.M.S.Y., Galil, M.S.A., Suresha, M.S., Sathish, M.A., and Nagendrappa, G., 2007, A simple spectrophotometric determination of phosphate in sugarcane juices, water, and detergent samples, E-J. Chem., 4 (4), 467–473.
[28] Topçu, A., and Pulatsü, S., 2014, Phosphorus fractions and cycling in the sediment of a shallow eutrophic pond, J. Agric. Sci., 20 (1), 63–70.
[29] Sengupta, S., Nawaz, T., and Beaudry, J., 2015, Nitrogen and phosphorus recovery from wastewater, Curr. Pollut. Rep., 1 (3), 155–166.
[30] Cerozi, B.S., and Fitzsimmons, K., 2016, The effect of pH on phosphorus availability and speciation in an aquaponics nutrient solution, Bioresour. Technol., 219, 778–781.
[31] Lei, Y., Song, B., van der Weijden, R.D., Saakes, M., and Buisman, C.J.N., 2017, Electrochemical induced calcium phosphate precipitation: importance of local pH, Environ. Sci. Technol., 51 (19), 11156–11164.
[32] De Saedeleer, V., Cappuyns, V., De Cooman, W., and Swennen, R., 2010, Influence of major elements on heavy metal composition of river sediments, Geol. Belg., 13 (3), 257–268.
[33] Jiang, M., Zeng, G., Zhang, C., Ma, X., Chen, M., Zhang, J., Lu, L., Yu, Q., Hu, L., and Liu, L., 2012, Assessment of heavy metal contamination in the surrounding soils and surface sediments in Xiawangang River, Qingshuitang District, PLoS One, 8 (8), e71176.
[34] Alamgir, M., Islam, M., Hossain, N., Kibria, M.G., and Rahman, M.M., 2015, Assessment of heavy metal contamination in urban soils of Chittagong City, Bangladesh, Int. J. Plant Soil Sci., 7 (6), 362–372.
[35] Zhang, C., Yu, Z., Zeng, G., Jiang, M., Yang, Z., Cui, F., Zhu, M., Shen, L., and Hu, L., 2014, Effects of sediment geochemical properties on heavy metal bioavailability, Environ. Int., 73, 270–281.
[36] Yao, Q., Wang, X., Jian, H., Chen, H., and Yu, Z., 2015, Characterization of the articles size fraction associated with heavy metals in suspended sediments of the Yellow River, Int. J. Environ. Res. Public Health, 12 (6), 6725–6744.
DOI: https://doi.org/10.22146/ijc.33613
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