Application of Sulfate-Reducing Bacteria for Treatment of Mine Drainages

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2006 Vol.43, Issue 2 Preview Page Next Page

Application of Sulfate-Reducing Bacteria for Treatment of Mine Drainages 광산배수처리를 위한 황산염환원균의 응용: 유경근, 정진기, 손정수, 이재천
Kyoungkeun Yoo, Jinki Jeong, Jeong-soo Sohn and Jae-chun Lee

30 April 2006. pp. 160-167

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Abstract

Sulfate-reducing bacteria(SRB) are obligate anaerobes and obtain energy from the process to reduce sulfates into sulfides. SRB have attracted interest in the treatment of acid mine drainage(AMD) because the biogenic sulfide reacts easily with heavy metal in solutions, and precipitates as metal sulfide. In the present article, the effects of pH, heavy metal ions, substrates, temperature, concentration of sulfides, types of reactor on the removal of heavy metal from mine drainage by SRB were summarized and discus sed.

Keywords

SRB(sulfate-reducing bacteria)

AMD(Acid mine drainage)

Metal sulfides. Biological treatment

황산염환원균은 황산염을 환원하여 황화수소를 생성하는 과정에서 에너지를 획득하는 편성혐기성세균이다. 황산염환원균에 의해 생성된 황화수소는 중금속과 반응하여 황화금속으로 침전하기 때문에 광산배수 중의 황산염과 중금속을 동시에 제거할 수 있는 세균으로서 주목을 받아왔다. 이 글에서는 황산염환원균을 이용한 광산배수 중의 중금속 제거에 미치는 pH, 중금속 이온, 기질, 온도, 황화수소의 농도, 반응기 등의 영향에 대하여 지금까지 발표된 연구결과들을 정리하고 고찰하였다.

키워드

황산염환원균

산성광산배수

금속 황화물

생물학적 처리

References

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김병홍, 1995, “미생물 생리학”, 아카데미서적, 서울, 한국, pp. 292-302.
대구광역시 달성군청, 1995, “달성광산 공해방지시설 설치방안 조사 연구,” 한국자원연구소, pp. 58-104.
백병천, 김광복, 1999, “황산염환원균을 이용한 폐광폐수의 중금속 제거,” 대한상하수도학회지, 13권, 2호, pp. 47-54.
송영채, 나승진, 백병천, 2000, “황산염환원균을 이용한 도금폐수의 혐기성 처리에 관한 연구,” 한국폐기물학회지, 17권, 6호, pp. 758-765.
석탄산업합리화사업단, 2005, “휴․폐금속광산 정밀실태 조사 연구,” 한국지질자원연구원, p. 90.
정권, 신재영, 정일현, 高見澤一裕, 유영식, “폐기물매립지 침출수에서 황산염환원균의 분포와 중금속 불용화역할,” 한국환경위생학회지, 23권, 3호, pp. 27-39.
정영욱, 2004, “석탄광의 광산배수처리기술 현황 및 전망”, 자원환경지질, 37권, 1호, pp. 107-111.
지상우, 김선준, 2003, “남한지역 탄전별 광산배수의 물리화학적 특성에 관한 연구,” 한국지구시스템공학회지, 40 권, 6호, pp. 467-468.
Barton, L. L. and Tomei, F. A., 1995, “Sulfate-Reducing Bacteria,”(L. L. Barton, ed.), Plenum Press, New York, USA, pp. 2-3.
Boshoff, G., Duncan, J., and Rose, P. D., 2004, “Tannery Effluent as a Carbon Source for Biological,” Water Research, Vol. 38, pp. 2651-2658.
Castro, H. F., Williams, N. H., and Ogram, A., 2000, “Phylogeny of Sulfate-Reducing Bacteria”, FEMS Microbiology Ecology, Vol. 31, pp. 1-9.
Chang, I. S., Shin, P. K., and Kim, B, H., 2000, “Biological Treatment of Acid Mine Drainage under Sulphate-Reducing Conditions with Solid Waste Materials as Substrate,” Water Research, Vol. 34, No. 4, pp. 1269- 1277.
Chen, B.-Y., Utgikar, V. P., Harmon, S. M., Tabak, H. H., Bishop, D. F., and Govind, R., 2000, “Studies on Biosorption of Zinc and Copper on Desulfovibrio desulfuricans,” International Biodeterioration & Biodegradation, Vol. 46, pp. 11-18.
Christensen, B., Laake, M., and Lien, T., 1996, “Treatment of Acid Mine Water by Sulfate-Reducing Bacteria; Results from a Bench Scale Experiment,” Water Research, Vol. 30, No. 7, pp. 1617-1624.
Cohen, R. R. H., 2005, “Use of Microbes for Cost Reduction of Metal Removal from Metals and Mining Industry Waste Streams,” Journal of Cleaner Production (in press).
Drury, W. J., 1999, “Treatment of Acid Mine Drainage with Anaerobic Solid-Substrate Reactors,” Water Environment Research, Vol. 71, pp. 1244-1250.
Dvorak, D. H., Hedin, R. S., Edenborn, H. M., and Mclntire, P. E., 1992, “Treatment of Metal-Contaminated Water Using Bacterial Sulfate Reduction: Results from Pilot-Scale Reactors,” Biotechnology and Bioengineering, Vol. 40, pp. 609-616.
Elliott, P., Ragusa, S., and Catcheside, D., 1998, “Growth of Sulfate-Reducing Bacteria under Acidic Conditions in an Upflow Anaerobic Bioreactor as a Treatment System for Acid Mine Drainage,” Water Research, Vol. 32, No. 12, pp. 3724-3730.
Garcia, C., Moreno, D. A., Ballester, A., Blazquez, M. L., and Gonzalez, F., 2001, “Bioremediation of an Industrial Acid Mine Water by Metal-Tolerant Sulphate-Reducing Bacteria,” Minerals Engineering, Vol. 14, No. 9, pp. 997-1008.
Gorny, N and Schink, B., 1994, “Anaerobic Degradation of Catechol by Desulfobacterium sp. Strain Cat2 Proceeds via Carboxylation to Protocatechuate,” Applied and Environmental Microbiology, Vol. 60, pp. 3396-3400.
Hammack, R. W. and Dijkman, H., 1999, “The application of Bacterial Sulfate Reduction Treatment to Severely contaminated Mine Waters: Results of Three Years of Pilot Plant Testing,” Proceedings of Copper 99-Cobre 99 International Conference, The Minerals, Metals & Materials Society, Phoenix, Arizona, October 10-13, Vol. 4, pp. 97-111.
Harris, M. A. and Ragusa, S., 2000, “Bacterial Mitigation of Pollutants in Acid Drainage Using Decomposable Plant Material and Sludge,” Environmental Geology, Vol. 40, pp. 195-215.
Harris, M. A. and Ragusa, S., 2001, “Bioremediation of Acid Mine Drainage Using Decomposable Plant Material in a Constant Flow Bioreactor,” Environmental Geology, Vol. 40, pp. 1192-1204.
Johnson, D. B. and Hallberg, K. B., 2005, “Acid Mine Drainage Remediation Options: a Review,” Science of the Total Environment, Vol. 338, pp. 3-14.
Johnson, D. B., 1995, “Acidophilic Microbial Communities: Candidates for Bioremediation of Acidic Mine Effluents,” International Biodeterioration & Biodegradation, Vol. 35, pp. 41-58.
Kaksonen, A. H., Riekkola-Vanhanen, M.-L., and Puhakka, J. A., 2003, “Optimization of Metal Sulphide Precipitation in Fluidized-bed Treatment of Acidic Wastewater,” Water Research, Vol. 37, pp. 255-266.
Kolmert, A. and Johnson, D. B., 2001, “Remediation of Acidic Waste Waters Using Immobilised, Acidophilic Sulfate-Reducing Bacteria,” Journal of Chemical Technology and Biotechnology, Vol. 76, pp. 836-843.
Kuever, J., Kulmer, J., Jannsen, S., Fischer, U., and Blotevogel, K.-H., 1993, “Isolation and Characterization of a New Spore-Forming Sulfate-Reducing Bacterium Growing by Complete Oxidation of Catechol,” Archives of Microbiology, Vol. 159, pp. 282-288.
Luptakova, A. and Kusnierova, M., 2005, “Bioremediation of Acid Mine Drainage Contaminated by SRB,” Hydrometallurgy, Vol. 77, pp. 97-102.
Okabe, S., Nielsen, P. H., and Characklis, W. G., 1992, “Factors Affecting Microbial Sulfate Reduction by Desulfovibrio desulfuricans in Continuous Culture:

Information

Publisher :The Korean Society of Mineral and Energy Resources Engineers
Publisher(Ko) :한국자원공학회
Journal Title :Journal of the Korean Society for Geosystem Engineering
Journal Title(Ko) :한국지구시스템공학회지
Volume : 43
No :2
Pages :160-167

[1] 과학기술부, 1999, “폐광산 복원기술,” 한국과학기술연구원, pp. 432-433.

[2] 김병홍, 1995, “미생물 생리학”, 아카데미서적, 서울, 한국, pp. 292-302.

[3] 대구광역시 달성군청, 1995, “달성광산 공해방지시설 설치방안 조사 연구,” 한국자원연구소, pp. 58-104.

[4] 백병천, 김광복, 1999, “황산염환원균을 이용한 폐광폐수의 중금속 제거,” 대한상하수도학회지, 13권, 2호, pp. 47-54.

[5] 송영채, 나승진, 백병천, 2000, “황산염환원균을 이용한 도금폐수의 혐기성 처리에 관한 연구,” 한국폐기물학회지, 17권, 6호, pp. 758-765.

[6] 석탄산업합리화사업단, 2005, “휴․폐금속광산 정밀실태 조사 연구,” 한국지질자원연구원, p. 90.

[7] 정권, 신재영, 정일현, 高見澤一裕, 유영식, “폐기물매립지 침출수에서 황산염환원균의 분포와 중금속 불용화역할,” 한국환경위생학회지, 23권, 3호, pp. 27-39.

[8] 정영욱, 2004, “석탄광의 광산배수처리기술 현황 및 전망”, 자원환경지질, 37권, 1호, pp. 107-111.

[9] 지상우, 김선준, 2003, “남한지역 탄전별 광산배수의 물리화학적 특성에 관한 연구,” 한국지구시스템공학회지, 40 권, 6호, pp. 467-468.

[10] Barton, L. L. and Tomei, F. A., 1995, “Sulfate-Reducing Bacteria,”(L. L. Barton, ed.), Plenum Press, New York, USA, pp. 2-3.

[11] Boshoff, G., Duncan, J., and Rose, P. D., 2004, “Tannery Effluent as a Carbon Source for Biological,” Water Research, Vol. 38, pp. 2651-2658.

[12] Castro, H. F., Williams, N. H., and Ogram, A., 2000, “Phylogeny of Sulfate-Reducing Bacteria”, FEMS Microbiology Ecology, Vol. 31, pp. 1-9.

[13] Chang, I. S., Shin, P. K., and Kim, B, H., 2000, “Biological Treatment of Acid Mine Drainage under Sulphate-Reducing Conditions with Solid Waste Materials as Substrate,” Water Research, Vol. 34, No. 4, pp. 1269- 1277.

[14] Chen, B.-Y., Utgikar, V. P., Harmon, S. M., Tabak, H. H., Bishop, D. F., and Govind, R., 2000, “Studies on Biosorption of Zinc and Copper on Desulfovibrio desulfuricans,” International Biodeterioration & Biodegradation, Vol. 46, pp. 11-18.

[15] Christensen, B., Laake, M., and Lien, T., 1996, “Treatment of Acid Mine Water by Sulfate-Reducing Bacteria; Results from a Bench Scale Experiment,” Water Research, Vol. 30, No. 7, pp. 1617-1624.

[16] Cohen, R. R. H., 2005, “Use of Microbes for Cost Reduction of Metal Removal from Metals and Mining Industry Waste Streams,” Journal of Cleaner Production (in press).

[17] Drury, W. J., 1999, “Treatment of Acid Mine Drainage with Anaerobic Solid-Substrate Reactors,” Water Environment Research, Vol. 71, pp. 1244-1250.

[18] Dvorak, D. H., Hedin, R. S., Edenborn, H. M., and Mclntire, P. E., 1992, “Treatment of Metal-Contaminated Water Using Bacterial Sulfate Reduction: Results from Pilot-Scale Reactors,” Biotechnology and Bioengineering, Vol. 40, pp. 609-616.

[19] Elliott, P., Ragusa, S., and Catcheside, D., 1998, “Growth of Sulfate-Reducing Bacteria under Acidic Conditions in an Upflow Anaerobic Bioreactor as a Treatment System for Acid Mine Drainage,” Water Research, Vol. 32, No. 12, pp. 3724-3730.

[20] Garcia, C., Moreno, D. A., Ballester, A., Blazquez, M. L., and Gonzalez, F., 2001, “Bioremediation of an Industrial Acid Mine Water by Metal-Tolerant Sulphate-Reducing Bacteria,” Minerals Engineering, Vol. 14, No. 9, pp. 997-1008.

[21] Gorny, N and Schink, B., 1994, “Anaerobic Degradation of Catechol by Desulfobacterium sp. Strain Cat2 Proceeds via Carboxylation to Protocatechuate,” Applied and Environmental Microbiology, Vol. 60, pp. 3396-3400.

[22] Hammack, R. W. and Dijkman, H., 1999, “The application of Bacterial Sulfate Reduction Treatment to Severely contaminated Mine Waters: Results of Three Years of Pilot Plant Testing,” Proceedings of Copper 99-Cobre 99 International Conference, The Minerals, Metals & Materials Society, Phoenix, Arizona, October 10-13, Vol. 4, pp. 97-111.

[23] Harris, M. A. and Ragusa, S., 2000, “Bacterial Mitigation of Pollutants in Acid Drainage Using Decomposable Plant Material and Sludge,” Environmental Geology, Vol. 40, pp. 195-215.

[24] Harris, M. A. and Ragusa, S., 2001, “Bioremediation of Acid Mine Drainage Using Decomposable Plant Material in a Constant Flow Bioreactor,” Environmental Geology, Vol. 40, pp. 1192-1204.

[25] Johnson, D. B. and Hallberg, K. B., 2005, “Acid Mine Drainage Remediation Options: a Review,” Science of the Total Environment, Vol. 338, pp. 3-14.

[26] Johnson, D. B., 1995, “Acidophilic Microbial Communities: Candidates for Bioremediation of Acidic Mine Effluents,” International Biodeterioration & Biodegradation, Vol. 35, pp. 41-58.

[27] Kaksonen, A. H., Riekkola-Vanhanen, M.-L., and Puhakka, J. A., 2003, “Optimization of Metal Sulphide Precipitation in Fluidized-bed Treatment of Acidic Wastewater,” Water Research, Vol. 37, pp. 255-266.

[28] Kolmert, A. and Johnson, D. B., 2001, “Remediation of Acidic Waste Waters Using Immobilised, Acidophilic Sulfate-Reducing Bacteria,” Journal of Chemical Technology and Biotechnology, Vol. 76, pp. 836-843.

[29] Kuever, J., Kulmer, J., Jannsen, S., Fischer, U., and Blotevogel, K.-H., 1993, “Isolation and Characterization of a New Spore-Forming Sulfate-Reducing Bacterium Growing by Complete Oxidation of Catechol,” Archives of Microbiology, Vol. 159, pp. 282-288.

[30] Luptakova, A. and Kusnierova, M., 2005, “Bioremediation of Acid Mine Drainage Contaminated by SRB,” Hydrometallurgy, Vol. 77, pp. 97-102.

[31] Okabe, S., Nielsen, P. H., and Characklis, W. G., 1992, “Factors Affecting Microbial Sulfate Reduction by Desulfovibrio desulfuricans in Continuous Culture:

Journal of the Korean Society of Mineral and Energy Resources Engineers ISSN:2288-0291(Print) 2288-2790(Online) 한국자원공학회지

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