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Mercury Ion Removal Using a Packed-Bed Column with Granular Aminated Chitosan  

JEON, CHOONC (Department of Environmental & Applied Chemical Engineering, Kangnung National University)
Publication Information
Journal of Microbiology and Biotechnology / v.15, no.3, 2005 , pp. 497-501 More about this Journal
Abstract
This study deals with the removal of mercury species using a packed-bed column with spherical aminated chitosan material. These adsorbents revealed a high adsorption capacity for mercury species. Experiments with feed solutions of 10 ppm Hg dissolved in distilled water showed an excellent removal with a sharp increase of the filter effluent concentration after a total throughput of 900 bed volumes of feed water. Up to $95\%$ desorption was reached by using 3 bed volumes of 0.01 N EDTA solution. EDTA could be recovered by means of sulfuric acid with about $75\%$ efficiency. Almost the same results were obtained in repeated sorption and desorption experiments at identical conditions. The experiments demonstrated that the sorbents possessed practically no sorption capacity for alkaline earth ions ($Ca^{2+}\;and\;Mg^{2+}$). Their influence on the sorption of mercury was negligible. In experiments with spiked tap water of the Karlsruhe Research Centre and a feed mercury concentration of 0.01 mg/l, the breakthrough of Hg was observed only after a total throughput of about 6,000 bed volumes of feed water.
Keywords
Biosorption; chitosan; mercury; packed-bed column; EDTA; desorption;
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  • Reference
1 Jeon, C. and W. H. Hoell. 2003. Chemical modification of chitosan and equilibrium study for mercury ion removal. Water Res. 37: 4770-4780   DOI   ScienceOn
2 Kim, Y. H. 1996. Heavy metal removal using chemically modified marine brown alga, Undaria pinnatifida. Ph.D Thesis, Seoul National University
3 Remmers, P. and K. D. Vorlop. 1992. Production of highly elastic polyvinyl alcohol biocatalyst beads and their use for continuous denitrification, pp. 939-942. In: Proceedings of the De CHEMA Biotechnology Conferences, Vol. 5, VCH, Weinheim
4 Zulfadhly, Z., M. D. Mashitah, and S. Bhatia. 2001. Heavy metals removal in fixed-bed column by the macro fungus Pycnoporus sanguineus. Environ. Poll. 112: 463-470   DOI   ScienceOn
5 Jha, I. N., L. Iyengar, and A. V. S. Rao. 1988. Removal of cadmium using chitosan. J. Environ. Eng. 114: 962-974   DOI   ScienceOn
6 Hoell, W. H., C. Bartosch, X. Zhao, and S. He. 2002. Elimination of trace heavy metals from drinking water by means of weakly basic anion exchangers. J. Water Supply: Research and Technology-AQUA 51(3): 165-172
7 Pradhan, S., S. Sarita, C. R. Lal, and L. P. Dorothy. 1998. Evaluation of metal biosorption efficiency of laboratory grown microcystis under various environmental conditions. J. Microbiol. Biotechnol. 8: 53-60
8 Bolto, B. A. and L. Pawlowski. 1987. Wastewater Treatment by Ion-exchange, pp. 195-202. E.&F.N. SPON, New York
9 Zuo, G. and M. Muhammed. 1995. Selective binding of mercury to thiourea-based coordinating resins. React. Polym. 27: 187-198   DOI   ScienceOn
10 Zhao, X., W. H. Hoell, and G. Yun. 2002. Elimination of cadmium trace contaminations from drinking water. Water Res. 36: 851-858   DOI   ScienceOn
11 Yang, T. C. and R. R. Zall. 1984. Absorption of metals by natural polymers generated from seafood processing waters. Ind. Eng. Chem. Prod. Res. Dev. 23: 168-172   DOI
12 Volesky, B. 1990. Biosorption of Heavy Metals, pp. 11-12. CRC Press, Inc
13 Brooks, C. S. 1991. Metal Recovery from Industrial Waters. Lewis publishers, Chelsea, MI
14 Heisen, T. Y. and G. L. Rorrer. 1995. Effects of acylation and crossIinking on the material properties and cadmium ion adsorption capacity of porous chitosan beads. Separ. Sci. Technol. 30(12): 2455-2475   DOI   ScienceOn
15 Pradip, P. K. and M. M. Sharma. 1991. Recovery of heterocyclic amines from dilute aqueous solution waste streams. Ind. Eng. Chem. Res. 30: 1880-1886   DOI