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The Effects of Biogeochemical Modification of Fe-Rich Smectite on the Fate of Pb

Published online by Cambridge University Press:  01 January 2024

Tae-hee Koo ,
Jee-young Kim ,
Jong-woo Choi  and
Jin-wook Kim
Tae-hee Koo
Affiliation:
Department of Earth System Sciences, Yonsei University, Seoul, Korea
Jee-young Kim
Affiliation:
Department of Earth System Sciences, Yonsei University, Seoul, Korea Environmental Infrastructure Research Department, Environmental Measurement & Analysis Center, National Institute of Environmental Research, Incheon, Korea
Jong-woo Choi
Affiliation:
Environmental Infrastructure Research Department, Environmental Measurement & Analysis Center, National Institute of Environmental Research, Incheon, Korea
Jin-wook Kim*
Affiliation:
Department of Earth System Sciences, Yonsei University, Seoul, Korea
*
*E-mail address of corresponding author: [email protected]
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Abstract

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Fe-rich smectite is ubiquitous in soil environments and closely linked to the fate and mobility of hazardous trace metals and particularly to the variations in the biogeochemical redox reactions of structural Fe that determine the sorption and desorption properties of clay minerals. The biotic/abiotic redox reactions of a Fe-rich smectite, nontronite (NAu-1), were performed at various reaction times using the Fe-reducing bacterium Shewanella oneidensis MR-1 at 30°C and Na-dithionite (Na2S2O4), respectively. The extent of biotic Fe-reduction of NAu-1 after 30 days of incubation reached up to 10.7% of total Fe and the range of abiotic Fe-reduction varied from 4.9–46.6% at reaction times of 5 min, 30 min, 1 h, and 4 h. The biotically and abiotically Fe-reduced NAu-1 samples were spiked with Pb concentrations of 0.07, 0.2, 0.5, and 1.0 mg/kg and incubated under aerobic or anaerobic conditions for 24 h.

The amounts of Pb in the supernatants were analyzed using an Inductively Coupled Plasma Mass Spectrometer (ICP-MS) and Multi-collector (MC)-ICP-MS. The amounts of Pb removed from the supernatants were negatively related to the extent of Fe(III) reduction in the abiotically Fe-reduced NAu-1 samples. In contrast, less Pb (~15%) was removed from the biotically Fe-reduced NAu-1 samples with a similar extent of Fe(III) reduction. Changes in the isotopic 208/204Pb ratio indicated that the lighter 204Pb isotope was preferentially adsorbed to the NAu-1 samples with less Fe reduction and indicated that variations in the net layer charge affected isotopic fractionation. Significant differences in the 208/204Pb ratios for NAu-1 samples that were biotically Fe-reduced under anaerobic conditions were measured and indicate that the reversibility of the structural/chemical modifications that occur under redox conditions can affect Pb removal and, thus, isotope fractionation. These results collectively infer that the biogeochemical properties of clay minerals should be considered in order to understand the fate of trace metals in natural environments.

Keywords

Abiotic ReductionFe-reducing MicrobeNontronitePb Isotopic CompositionPb Removal
Type
Article
Information
Clays and Clay Minerals , Volume 65 , Issue 6 , December 2017 , pp. 410 - 416
Copyright
Copyright © Clay Minerals Society 2017

References

Benjamin, M.M. and Leckie, J.O., 1981 Multiple-site adsorption of Cd, Cu, Zn, and Pb on amorphous iron oxyhydroxide Journal of Colloid and Interface Science 79 209221.CrossRefGoogle Scholar
Bhattacharyya, K.G. and Gupta, S.S., 2006 Kaolinite, montmorillonite, and their modified derivatives as adsorbents for removal of Cu(II) from aqueous solution Separation and Purification Technology 50 388397.CrossRefGoogle Scholar
Bishop, M.E. Glasser, P. Dong, H. Arey, B. and Kovarik, L., 2014 Reduction and immobilization of hexavalent chromium by microbially reduced Fe-bearing clay minerals Geochmica et Cosmochimica Acta 133 186203.CrossRefGoogle Scholar
Cheng, H. and Hu, Y., 2010 Lead (Pb) isotopic fingerprinting and its applications in lead pollution studies in China: A review Environmental Pollution 158 11341146.CrossRefGoogle Scholar
Chisholm-Brause, C.J. Berg, J.M. Matzner, R.A. and Morris, D.E., 2001 Uranium(VI) sorption complexes on montmorillonite as a function of solution chemistry Journal of Colloid and Interface Science 233 3849.CrossRefGoogle ScholarPubMed
Choi, J.W. Yoo, E.J. Kim, J.Y. Hwang, J.Y. Lee, K. Lee, W.S. Han, J.S. and Lee, K.S., 2013 Pb concentrations and isotopic compositions in the soil and sediments around the abandoned mine in southwest of Korea Journal of Agricultural Chemistry and Environment 2 101108.CrossRefGoogle Scholar
Dong, H. Jaisi, D.P. Kim, J.W. and Zhang, G., 2009 Microbe-clay mineral interactions American Mineralogist 94 15051519.CrossRefGoogle Scholar
Gadde, R. and Laitinen, H.A., 1974 Studies of heavy metal adsorption by hydrous iron and manganese oxides Analytical Chemistry 46 20222026.CrossRefGoogle Scholar
Gupta, S.S. and Bhattacharyya, K.G., 2008 Immobilization of Pb(II), Cd(II) and Ni(II) ions on kaolinite and montmorillonite surfaces from aqueous medium Journal of Environmental Management 87 4658.CrossRefGoogle Scholar
Jaisi, D.P. Dong, H. Kim, J.W. He, Z. and Morton, J.P., 2007 Nontronite particle aggregation induced by microbial Fe(III) reduction and exopolysaccharide production Clays and Clay Minerals 55 96107.CrossRefGoogle Scholar
Jaisi, D.P. Ji, S. Dong, H. Blake, R.E. Eberl, D.D. and Kim, J.W., 2008 Role of microbial Fe(III) reduction and solution chemistry in aggregation and settling of suspended particles in the Mississippi river delta plain, Louisiana, USA Clays and Clay Minerals 56 416428.CrossRefGoogle Scholar
Jaisi, D.P. Dong, H. Plymale, A.E. Fredrickson, J.K. Zachara, J.M. Heald, S. and Liu, C., 2009 Reduction and long-term immobilization of technetium by Fe(II) associated with clay mineral nontronite Chemical Geology 264 127138.CrossRefGoogle Scholar
Jiang, M. Jin, X. Lu, X. and Chen, Z., 2010 Adsorption of Pb(II), Cd(II), Ni(II) and Cu(II) onto natural kaolinite clay Desalination 252 3339.CrossRefGoogle Scholar
Kersten, M. Garbe-Schoenberg, C.D. Thomsen, S. Anagnostou, C. and Sioulas, A., 1997 Source apportionment of Pb pollution in the coastal waters of Elefsis Bay, Greece Environmental Science & Technology 31 12951301.CrossRefGoogle Scholar
Kim, JW D ong, H. Seabaugh, J. Newell, S.W. and Eberl, D.D., 2004 Role of microbes in the smectite-to-illite reaction Science 303 830832.CrossRefGoogle ScholarPubMed
Kim, J.W. Furukawa, Y. Dong, H. and Newell, S.W., 2005 The effect of microbial Fe(III) reduction on smectite flocculation Clays and Clay Minerals 53 572579.CrossRefGoogle Scholar
Komlos, J. Peacock, A. Kukkadapu, R.K. and Jaffé, P.R., 2008 Long-term dynamics of uranium reduction/reoxidation under low sulfate conditions Geochimica et Cosmochimica Acta 72 36033615.CrossRefGoogle Scholar
Komadel, P. Madejova, J. and Stucki, J.W., 1995 Reduction and reoxidation of nontronite: Questions of reversibility Clays and Clay Minerals 43 105110.CrossRefGoogle Scholar
Koo, T.H. Jang, Y.N. Kogure, T. Kim, J.H. Park, B.C. Sunwoo, D. and Kim, J.W., 2014 Structural and chemical modification of nontronite associated with microbial Fe(III) reduction: Indicators of “illitization.” Chemical Geology 377 8795.CrossRefGoogle Scholar
Lee, K. Kostka, J.E. and Stucki, J.W., 2006 Comparisons of structural iron reduction in smectites by bacteria and dithionite: An infrared spectroscopic study Clays and Clay Minerals 54 197210.CrossRefGoogle Scholar
Lu, P. Nuhfer, N.T. Kelly, S. Li, Q. Konishi, H. Elswick, E. and Zhu, C., 2011 Lead coprecipitation with iron oxyhydroxide nano-particles Geochimica et Cosmochimica Acta 75 45474561.CrossRefGoogle Scholar
MacKenzie, A.B. and Pulford, I.D., 2002 Investigation of contaminant metal dispersal from a disused mine site at Tyndrum, Scotland, using concentration gradients and stable Pb isotope ratios Applied Geochemistry 17 10931103.CrossRefGoogle Scholar
McKinley, J.P. Zachara, J.M. Smith, S.C. and Turner, G.D., 1995 The influence of uranyl hydrolysis and multiple sitebinding reactions on adsorption of U(VI) to montmorillonite Clays and Clay Minerals 43 586598.CrossRefGoogle Scholar
Myers, C.R. and Nealson, K.H., 1988 Bacterial manganese reduction and growth with manganese oxide as the sole electron acceptor Science 240 13191321.CrossRefGoogle ScholarPubMed
Neumann, A. Oslon, T.L. and Scherer, M., 2013 Spectroscopic evidence for Fe(II)-Fe(III) electron transfer at clay mineral edge and basal sites Environmental Science & Technology 47 69696977.CrossRefGoogle ScholarPubMed
Pentrakova, L. Su, K. Pentrak, M. and Stucki, J.W., 2013 A review of microbial redox interactions with structural Fe in clay minerals Clay Minerals 48 543560.CrossRefGoogle Scholar
Plus, R.W. Powell, R.M. Clark, D. and Eldred, C.J., 1991 Effects of pH, solid/solution ratio, ionic strength, and organic acids on Pb and Cd sorption on kaolinite Water Air and Soil Pollution, 5758, 423-430.Google Scholar
Ribeiro, F.R. Fabris, J.D. Kostka, J.E. Komadel, P. and Stucki, J.W., 2009 Comparisons of structural iron reduction in smectites by bacteria and dithionite: II A variabletemperature Mössbauer spectroscopic study of Garfield nontronite. Pure and Applied Chemistry 81 14991509.Google Scholar
Rosman, K.J.R. Chisolm, W. Boutron, C.F. Candelone, J.P. and Patterson, C.C., 1994 Anthropogenic lead isotopes in Antarctica Geophysical Research Letters 21 26692672.CrossRefGoogle Scholar
Singh, R. Dong, H. Zeng, Q. Zhang, L. and Rengasamy, K., 2017 Hexavalent chromium removal by chitosan modifiedbioreduced nontronite Geochimica et Cosmochimica Acta 210 2541.CrossRefGoogle Scholar
Stucki, J.W., 1981 The Quantitative assay of minerals for Fe2+ and Fe3+ using 1,10-phenanthroline: II. A photochemical method Soil Science Society of America Journal 45 638641.CrossRefGoogle Scholar
Stucki, J.W. Golden, D.C. and Roth, C.B., 1984 Preparation and handling of dithionite-reduced smectite suspensions Clays and Clay Minerals 32 191197.CrossRefGoogle Scholar
Swallow, C.K. Hume, D.N. and Morel, F.M.M., 1980 Sorption of copper and lead by hydrous ferric oxide Environmental Science & Technology 11 13261331.CrossRefGoogle Scholar
Tanabe, K., 2012 Solid Acids and Bases: Their Catalytic Properties Amsterdam Elsevier.Google Scholar
Tsunashima, A. Brindley, G.W. and Bastovanov, M., 1981 Adsorption of Uranium from solutions by montmorillonite: Compositions and properties of uranyl montmorillonites Clays and Clay Minerals 29 1016.CrossRefGoogle Scholar
Zhang, G. Dong, H. Kim, J.W. and Eberl, D.D., 2007 Microbial reduction of structural Fe3+ in nontronite by a thermophilic bacterium and its role in promoting the smectite to illite reaction American Mineralogist 92 14111419.CrossRefGoogle Scholar