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In situ remediation of arsenic-rich mine tailings using slag zero valence iron

Published online by Cambridge University Press:  27 April 2020

Tingting Yue
Affiliation:
School of Resources and Environment, Southwest University, Chongqing400715China The Key Laboratory of Solid Waste Treatment and Resource, Ministry of Education, Southwest University of Science and Technology, Mianyang621010China
Shu Chen
Affiliation:
The Key Laboratory of Solid Waste Treatment and Resource, Ministry of Education, Southwest University of Science and Technology, Mianyang621010China
Jing Liu*
Affiliation:
School of Resources and Environment, Southwest University, Chongqing400715China
*
*Author for correspondence: Jing Liu, Email: [email protected]

Abstract

Arsenopyrite (FeAsS) and realgar (As4S4) are two common arsenic minerals that often cause serious environmental issues. Centralised treatment of arsenic-containing tailings can reduce land occupation and save management costs. The current work examined the remediation schemes of tailings from Hunan Province, China, where by different tailings containing arsenopyrite and realgar were blended with exogenous slag zero valence iron (ZVI). Introducing Fe-oxidising bacteria (Acidithiobacillus ferrooxidans) recreates a biologically oxidative environment. All bioleaching experiments were done over three stages, each for 7 days and the solid phase of all tests was characterised by scanning electron microscopy, X-ray diffraction, Fourier-transform infrared spectroscopy, X-ray photoelectron spectroscopy and selective extraction analyses. The results showed that the mixture group reduced arsenic release by 72.9–74.7% compared with the control group. The addition of 0.2 g ZVI clearly decreased arsenic release, and the addition of 4.0 g ZVI led to the lowest arsenic release among all tests. The decrease of arsenic released from the tailings was due to the adsorption and uptake of arsenic by secondary iron-containing minerals and Fe–As(V) secondary mineralisation. The addition of large amounts of ZVI reduced the arsenic detected in the amorphous Fe precipitates. Therefore, a low cost and integrated strategy to reduce arsenic release from tailings is to mix two typical tailings and apply exogenous slag ZVI, which can apply to the in situ remediation of two kinds or more arsenic-containing tailings.

Type
Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2020

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Footnotes

Associate Editor: Runliang Zhu

References

Bao, Z. (1991) A discussion on gold potential of pyrite and arsenopyrite in gold-bearing deposit, Hunan Province (in Chinese). Mineral Resources & Geology, 5, 368374.Google Scholar
Baragaño, D., Alonso, J., Gallego, J., Lobo, M. and Gil-Díaz, M. (2020) Zero valent iron and goethite nanoparticles as new promising remediation techniques for As-polluted soils. Chemosphere, 238, 124624.CrossRefGoogle ScholarPubMed
Bertocchi, A.F., Ghiani, M., Peretti, R. and Zucca, A. (2006) Red mud and fly ash for remediation of mine sites contaminated with As, Cd, Cu, Pb and Zn. Journal of Hazardous Materials, 134, 112119.CrossRefGoogle ScholarPubMed
Bluteau, M.C. and Demopoulos, G.P. (2007) The incongruent dissolution of scorodite — solubility, kinetics and mechanism. Hydrometallurgy, 87, 163177.CrossRefGoogle Scholar
Bowell, R., Alpers, C., Jamieson, H., Nordstrom, K. and Majzlan, J. (2014) Arsenic: Environmental Geochemistry, Mineralogy, and Microbiology. Walter de Gruyter GmbH & Co KG, Berlin.Google Scholar
Carlson, L., Bigham, J.M., Schwertmann, U., Kyek, A. and Wagner, F. (2002) Scavenging of As from acid mine drainage by schwertmannite and ferrihydrite: A comparison with synthetic analogues. Environmental Science & Technology, 36, 17121719.CrossRefGoogle ScholarPubMed
Chang-Li, M.O., Feng-Chang, W.U., Zhi-You, F.U., Zhu, J. and Ran, L. (2013) Antimony, arsenic and mercury pollution in agricultural soil of antimony mine area in Xikuangshan, Hunan. Acta Mineralogica Sinica, 33, 344350.Google Scholar
Chowdhury, T.R., Mandal, B.K., Samanta, G., Basu, G.K., Chowdhury, P.P., Chanda, C.R., Karan, N.K., Lodh, D., Dhar, R.K. and Das, D. (1997) Arsenic in groundwater in six districts of West Bengal, India: The biggest arsenic calamity in the world: The status report up to August, 1995. Pp. 93111 in: Arsenic (Abernathy, C.O., Calderon, R.L. and Chappell, W.R., editors). Springer, Dordrecht, The Netherlands.CrossRefGoogle Scholar
Corkhill, C.L. and Vaughan, D.J. (2009) Arsenopyrite oxidation – a review. Applied Geochemistry, 24, 23422361.CrossRefGoogle Scholar
Deng Sha Gu Guohua Xu Baoke Li Lijuan Wu and Bichao. (2018) Surface characterization of arsenopyrite during chemical and biological oxidation. Science of the Total Environment, 626, 349356.CrossRefGoogle Scholar
Dermatas, D., Moon, D.H., Menounou, N. and Xiaoguang Meng, R.H. (2004) An evaluation of arsenic release from monolithic solids using a modified semi-dynamic leaching test. Journal of Hazardous Materials, 116, 2538.CrossRefGoogle ScholarPubMed
Drahota, P., Mihaljevič, M., Grygar, T., Rohovec, J. and Pertold, Z. (2011) Seasonal variations of Zn, Cu, As and Mo in arsenic-rich stream at the Mokrsko gold deposit, Czech Republic. Environmental Earth Sciences, 62, 429441.CrossRefGoogle Scholar
Fan, L., Zhao, F., Liu, J. and Frost, R.L. (2018a) The As behavior of natural arsenical-containing colloidal ferric oxyhydroxide reacted with sulfate reducing bacteria. Chemical Engineering Journal, 332, 183191.CrossRefGoogle Scholar
Fan, L., Zhao, F., Liu, J. and Hudson-Edwards, K.A. (2018b) Dissolution of realgar by Acidithiobacillus ferrooxidans in the presence and absence of zerovalent iron: Implications for remediation of iron-deficient realgar tailings. Chemosphere, 209, 381391.CrossRefGoogle Scholar
Gil-Díaz, M., Rodríguez-Valdés, E., Alonso, J., Baragaño, D., Gallego, J.R. and Lobo, M.C. (2019) Nanoremediation and long-term monitoring of brownfield soil highly polluted with As and Hg. Science of The Total Environment, 675, 165175.CrossRefGoogle ScholarPubMed
Goldberg, S. and Johnston, C.T. (2001) Mechanisms of arsenic adsorption on amorphous oxides evaluated using macroscopic measurements, vibrational spectroscopy, and surface complexation modeling. Journal of Colloid and Interface Science, 234, 204216.CrossRefGoogle ScholarPubMed
Goossens, D., Buck, B.J., Teng, Y. and Mclaurin, B.T. (2015) Surface and airborne arsenic concentrations in a recreational site near Las Vegas, Nevada, USA. PLOS One, 10, e0124271.CrossRefGoogle Scholar
Gruyter, W.D. (2014) Arsenic: Environmental geochemistry, mineralogy, and microbiology. BMJ, 1, 740742.Google Scholar
He, H., Cao, J. and Duan, N. (2019) Defects and their behaviors in mineral dissolution under water environment: A review. Science of the Total Environment, 651, 22082217.CrossRefGoogle ScholarPubMed
Henao, D.M.O. and Godoy, M.A.M. (2010) Jarosite pseudomorph formation from arsenopyrite oxidation using Acidithiobacillus ferrooxidans. Hydrometallurgy, 104, 162168.CrossRefGoogle Scholar
Henke, K. (2009) Arsenic: Environmental Chemistry, Health Threats and Waste Treatment. John Wiley & Sons, Hoboken, New Jersey, USA.CrossRefGoogle Scholar
Hudson-Edwards, K.A. (2016) Tackling mine wastes. Science, 352, 288290.CrossRefGoogle ScholarPubMed
Hui, Z., Ma, D. and Hu, X. (2002) Arsenic pollution in groundwater from Hetao Area, China. Environmental Geology, 41, 638643.Google Scholar
Kim, K.R., Lee, B.-T. and Kim, K.-W. (2012) Arsenic stabilization in mine tailings using nano-sized magnetite and zero valent iron with the enhancement of mobility by surface coating. Journal of Geochemical Exploration, 113, 124129.CrossRefGoogle Scholar
Ladeira, A.C. and Ciminelli, V.S. (2004) Adsorption and desorption of arsenic on an oxisol and its constituents. Water Research, 38, 20872094.CrossRefGoogle Scholar
Langmuir, D., Mahoney, J. and Rowson, J. (2006) Solubility products of amorphous ferric arsenate and crystalline scorodite (FeAsO4⋅2H2O) and their application to arsenic behavior in buried mine tailings. Geochimica et Cosmochimica Acta, 70, 29422956.CrossRefGoogle Scholar
Lengke, M.F. and Tempel, R.N. (2003) Natural realgar and amorphous AsS oxidation kinetics. Geochimica et Cosmochimica Acta, 67, 859871.CrossRefGoogle Scholar
Lingmei, W., Chaoyang, W., Linsheng, Y. (2009) Using rice as bio-indicator for heavy metal contamination, a study in the Pb–Zn mining and smelting area at Shuikoushan, Hunan Province, China. Asian Journal of Ecotoxicology, 4, 373381 [in Chinese].Google Scholar
Liu, F., Zhang, W., Tao, L., Hao, B. and Zhang, J. (2019) Simultaneously photocatalytic redox and removal of chromium(VI) and arsenic(III) by hydrothermal carbon-sphere@nano-Fe3O4. Environmental Science: Nano, 6, 937947.Google Scholar
Liu, J., Cheng, H., Zhao, F., Dong, F. and Frost, R.L. (2013) Effect of reactive bed mineralogy on arsenic retention and permeability of synthetic arsenic-containing acid mine drainage. Journal of Colloid & Interface Science, 394, 530538.CrossRefGoogle ScholarPubMed
Liu, J., Deng, S., Zhao, F., Cheng, H. and Frost, R.L. (2014) Spectroscopic characterization and solubility investigation on the effects of As(V) on mineral structure tooeleite (Fe₆(AsO₃)₂SO₄(OH)₂⋅H₂O). Spectrochimica Acta Part A: Molecular and Biomolecular Spectrosccopy, 134C, 428433.Google Scholar
Liu, J., He, L., Chen, S., Dong, F. and Frost, R.L. (2016) Characterization of the dissolution of tooeleite under Acidithiobacillus ferrooxidans relevant to mineral trap for arsenic removal. Desalination and Water Treatment, 57, 1510815114.CrossRefGoogle Scholar
Liu, J., He, L., Dong, F. and Frost, R.L. (2017a) Infrared and Raman spectroscopic characterizations on new Fe sulphoarsenate hilarionite (Fe2((III))(SO4)(AsO4)(OH)⋅6H2O): Implications for arsenic mineralogy in supergene environment of mine area. Spectrochimica Acta Part A: Molecular and Biomolecular Spectrosccopy, 170, 913.CrossRefGoogle Scholar
Liu, J., Zhou, L., Dong, F. and Hudson-Edwards, K.A. (2017b) Enhancing As(V) adsorption and passivation using biologically formed nano-sized FeS coatings on limestone: Implications for acid mine drainage treatment and neutralization. Chemosphere, 168, 529538.CrossRefGoogle Scholar
Liu, Y.J., Gan, Y.Q., Wang, Y.X., Ma, T. and Li, J.L. (2010) An experimental study on removing arsenic from water using iron slag. Environmental Science & Technology, 33, 166170 [in Chinese].Google Scholar
Lockwood, C.L., Mortimer, R.J.G., Stewart, D.I., Mayes, W.M., Peacock, C.L., Polya, D.A., Lythgoe, P.R., Lehoux, A.P., Gruiz, K. and Burke, I.T. (2014) Mobilisation of arsenic from bauxite residue (red mud) affected soils: Effect of pH and redox conditions. Applied Geochemistry, 51, 268277.CrossRefGoogle Scholar
Loehr, T.M. and Plane, R.A. (1968) Raman spectra and structures of arsenious acid and arsenites in aqueous solution. Inorganic Chemistry, 7, 17081714.CrossRefGoogle Scholar
Lottermoser, B. (2007) Mine Wastes (second edition): Characterization, Treatment, Environmental Impacts. Springer, Berline, 304 pp.Google Scholar
Mohapatra, M., Sahoo, S.K., Anand, S. and Das, R.P. (2006) Removal of As(V) by Cu(II)-, Ni(II)-, or Co(II)-doped goethite samples. Journal of Colloid & Interface Science, 298, 612.CrossRefGoogle ScholarPubMed
Nesbitt, H.W. and Muir, I.J. (1998) Oxidation states and speciation of secondary products on pyrite and arsenopyrite reacted with mine waste waters and air. Mineralogy & Petrology, 62, 123144.CrossRefGoogle Scholar
Ouyang, B., Lu, X., Liu, H., Li, J., Zhu, T., Zhu, X., Lu, J. and Wang, R. (2014) Reduction of jarosite by Shewanella oneidensis MR-1 and secondary mineralization. Geochimica et Cosmochimica Acta, 124, 5471.Google Scholar
Pu, W. (1950) The geology of Sn-As ore in Anyuan area of Bing country, Hunan Province, China. Geological Review, 6, 176 [in Chinese].Google Scholar
Qiao, J.T., Liu, T.X., Wang, X.Q., Li, F.B., Lv, Y.H., Cui, J.H., Zeng, X.D., Yuan, Y.Z. and Liu, C.P. (2017) Simultaneous alleviation of cadmium and arsenic accumulation in rice by applying zero-valent iron and biochar to contaminated paddy soils. Chemosphere, 195, 260271.CrossRefGoogle ScholarPubMed
Rodríguez-Lado, L., Sun, G., Berg, M., Zhang, Q., Xue, H., Zheng, Q. and Johnson, C.A. (2013) Groundwater arsenic contamination throughout China. Science, 341, 866868.CrossRefGoogle ScholarPubMed
Schwertmann, U. and Cornell, R.M. (1993) Iron oxides in laboratory. Soil Science, 156, 281282.CrossRefGoogle Scholar
Shelobolina, E.S., Avakyan, Z.A. and Karavaiko, G.I. (1999) Transformation of Iron-Containing Minerals in Kaolin During Growth of a Mixed Bacterial Culture Derived from Kaolin. Springer, Berlin.CrossRefGoogle Scholar
Shrestha, R.R., Shrestha, M.P., Upadhyay, N.P., Pradhan, R., Khadka, R., Maskey, A., Maharjan, M., Tuladhar, S., Dahal, B.M. and Shrestha, K. (2003) Groundwater arsenic contamination, its health impact and mitigation program in Nepal. Journal of Environmental Science and Health Part A: Toxic/Hazardous Substances and Environmental Engineering, 38, 185200.CrossRefGoogle ScholarPubMed
Silverman, M.P. and Lundgren, D.G. (1959) Studies on the chemoautotrophic iron bacterium Ferrobacillus ferrooxidans: I. An improved medium and a harvesting procedure for securing high cell yields. Journal of Bacteriology, 77, 642647.Google Scholar
Singer, P.C. and Stumm, W. (1970) Acidic mine drainage: The rate-determining step. Science, 167, 1121.CrossRefGoogle ScholarPubMed
Šlejkovec, Z., Elteren, J.T.v., Glass, H.-J., Jeran, Z. and Jaćimović, R. (2010) Speciation analysis to unravel the soil-to-plant transfer in highly arsenic-contaminated areas in Cornwall (UK). International Journal of Environmental Analytical Chemistry, 90, 784796.CrossRefGoogle Scholar
Smedley, P.L and Kinniburgh and, D.G. (2002) A review of the source, behaviour and distribution of arsenic in natural waters. Applied Geochemistry, 17, 517568.CrossRefGoogle Scholar
Su, H., Fang, Z., Tsang, P.E., Fang, J. and Zhao, D. (2016) Stabilisation of nanoscale zero-valent iron with biochar for enhanced transport and in-situ remediation of hexavalent chromium in soil. Environmental Pollution, 214, 94100.CrossRefGoogle ScholarPubMed
Tang, J., Liao, Y., Yang, Z., Chai, L. and Yang, W. (2016) Characterization of arsenic serious-contaminated soils from Shimen realgar mine area, the Asian largest realgar deposit in China. Journal of Soils & Sediments, 16, 15191528.CrossRefGoogle Scholar
Teixeira, M.C. and Ciminelli, V.S. (2005) Development of a biosorbent for arsenite: Structural modeling based on X-ray spectroscopy. Environmental Science & Technology, 39, 895900.CrossRefGoogle ScholarPubMed
Tossell, J.A. (1997) Theoretical studies on arsenic oxide and hydroxide species in minerals and in aqueous solution. Geochimica et Cosmochimica Acta, 61, 16131623.CrossRefGoogle Scholar
Vítková, M., Puschenreiter, M. and Komárek, M. (2018) Effect of nano zero-valent iron application on As, Cd, Pb, and Zn availability in the rhizosphere of metal(loid) contaminated soils. Chemosphere, 200, 217226.CrossRefGoogle ScholarPubMed
Van Den Berghe, M.D., Jamieson, H.E. and Palmer, M.J. (2018) Arsenic mobility and characterization in lakes impacted by gold ore roasting, Yellowknife, NWT, Canada. Environmental Pollution, 234, 630641.CrossRefGoogle ScholarPubMed
Wang, Y. and Reardon, E.J. (2001) A siderite/limestone reactor to remove arsenic and cadmium from wastewaters. Applied Geochemistry, 16, 12411249.CrossRefGoogle Scholar
Wang, Z., He, H., Yan, Y. and Wu, C. (1999) Arsenic exposure of residents in areas near Shimen arsenic mine. Journal of Hygiene Research, 28, 1214.Google ScholarPubMed
Xiang, B.Z., Jiang, W.R. and Min, B.J. (2000) Typomorphic characteristics of arsenopyrite in precambrian gold deposit, Hunan. Gold Geology, 6, 3945.Google Scholar
Zhu, X., Wang, R., Lu, X., Liu, H., Li, J., Ouyang, B. and Lu, J. and Xiancai, . (2015) Secondary minerals of weathered orpiment-realgar-bearing tailings in Shimen Carbonate-Type Realgar Mine, Changde, central China. Mineralogy and Petrology, 109, 115.CrossRefGoogle Scholar
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