Demystifying MIC mechanisms

NACE - International Corrosion Conference Series

Volumn , Issue , 2010, Pages

  Gu, Tingyue ^a   Xu, Dake ^a  

^a Ohio University   (United States)

Author keywords

Acid reduction; APB; Mechanism; MIC; Model; Proton reduction; SRB; Sulfate reduction

Indexed keywords

APB; MIC; PROTON REDUCTION; SRB; SULFATE REDUCTION;

BACTERIOLOGY; BIOCHEMISTRY; COMPUTER SIMULATION; CORROSION; GAS INDUSTRY; PROTONS; RESERVOIRS (WATER);

REDUCTION;

EID: 79953001637     PISSN: 03614409     EISSN: None     Source Type: Book Series    
DOI: None     Document Type: Conference Paper

References (31)

1. H.A. Videla, Manual of Biocorrosion, Lewis Publishers, Boca Raton, Florida, 1996.
2. C. A. H. von Wolzogen Kuhr, L.S. Vlugt vander, "The graphitization, of cast iron as an electrochemical process in anaerobic soils," Water, 147-165, 1934.
3. W.S. Borenstein, Microbiologically Influenced Corrosion Handbook, Industrial Press, New York, 1994.
4. D. Thierry, W. Sand, "Microbially Influenced Corrosion." In: Corrosion Mechanisms in Theory and Practice, P. Marcus, J. Oudar (eds.), pp. 457-499, Marcel Dekker, New York, 1995.
5. H.D. Peck, "Bioenergetic Strategies of the Sulfate-Reducing Bacteria," in The Sulfate- Reducing Bacteria: Contemporary Perspectives, Odom, J.M., Singleton, R., Jr. (eds.), p. 57, Springer, Berlin-New York, 1993.
6. L.G. Ljungdahl, M.W. Adams, L.L. Barton, L.G. Ferry, M.K. Johnson, Biochemistry and Physiology of Anaerobic Bacteria, pp. 20-35, 67-85, 99-113, 252-260, Springer, New York, 2003.
7. T. Gu, K. Zhao, S. Nesic, "A Practical Mechanistic Model for MIC Based on a Biocatalytic Cathodic Sulfate Reduction Theory," CORROSION/2009, Paper No. 09390. (Houston, TX: NACE 2009)
8. I.B. Beech, C.C. Gaylarde, "Recent advances in the study of biocorrosion - an overview," Rev Microbiol, 30, 177-190, 1999.
9. J.M. Odom, R. Singleton Jr. (eds.), The Sulfate-Reducing Bacteria: Contemporary Perspectives, pp. 41-76, Springer, Berlin-New York, 1993.
10. S.B. Axelsen, T. Rogne, "Do micro-organisms 'eat' metal?" Microbiolgically influenced corrosion of industrial materials, Contract No. BRRT-CT98-5084, 1998.
11. W.A. Hamilton, "Bioenergetics of sulphate-reducing bacteria in relation to their environmental impact," Biodegradation, 9, 201-212, 1998.
12. J. Larsen, B. Dunsmore, C. Schwermer, "Investigation Into Halfdan Water Injection Biofilm Using Chemical Microsensors," CORROSION/2007, Paper No. 07507. (Houston, TX; NACE, 2007)
13. B. Chardin, M.T. Giudici-Orticoni, G. De Luca, B. Guigliarelli, M. Bruschi, "Hydrogenases in sulfate-reducing bacteria function as chromium reductase," Appl Microbiol Biotechnol, 63, 315-321, 2003. (Pubitemid 38130580)
14. S. Da Silva, R. Basséguy, A, Bergel, "The role of hydrogenases in the anaerobic microbiologically influenced corrosion of steels," Bioelectrochemistry, 56(1-2) 77-79, 2002. (Pubitemid 34496978)
15. S. Da Silva, R. Basséguy, A., Bergel, "Electron transfer between hydrogenase and 316L stainless steel:identification of a hydrogenase-catalyzed cathodic reaction in anaerobic MIC," J Electroanal Chem, 561, 93-102, 2004.
16. I.B. Beech, "Sulfate-reducing bacteria in biofilms on metallic materials and corrosion," Microbiology Today, 30, 115-117, 2003.
17. A.M. Brennenstuhl, T.S. Gendron, R. Cleland, "Mechanisms of underdeposit corrosion in fresh-water cooled austenitic alloy heat exchangers," Corrosion Science, 35, 699-711, 1993.
18. W. Liamleam, A.P. Annachhatre, "Electron donors for biological sulfate reduction," Biotechnol Adv, 25(5) 452-63, 2007. (Pubitemid 47049788)
19. C.G. Peng, "Charteriazation and pridiction of biodigradation in aquatic systems." Ph.D. dissertation, University of Wisconsin-Madison, 1992.
20. O.J. Hao, "Discussion of Modeling of anaerobic corrosion influenced by sulfatereducing bacteria." Wat Environ Res, 67(5) 875-876, 1995.
21. M.J. Vieira, L.F. Melo, M.M Pinheiro, "Biofilm formation: hydrodynamic effects on internal diffusion and structure," Biofouling, 7, 67-80, 1993.
22. L. Ocando, M.F. de Romero, O. Pérez, O.T. de Rincón, E. León, L. Atencio, "Evaluation of pH and H2S on biofilms generated by sulfate-reducing bacteria: influence of ferrous ions," CORROSION/2007, Paper No. 07528. (Houston, TX: NACE, 2007)
23. R. Zuo, "Biofilms: strategies for metal corrosion inhibition employing Microorganisms," Appl Microbiol Biotechnol, 76, 1245-1253, 2007. (Pubitemid 47459791)
24. M. de Romero, O. de Rincón, L. Ocando, "Cathodic protection efficiency in the presence of SRB: State of the art," CORROSION 2009, Paper No. 09407. (Houston, TX: NACE, 2009)
25. J.S. Lee, R.I. Ray, "Comparison of Key West and Persian Gulf seawaters," CORROSION/2007, Paper No. 518. (Houston, TX: NACE, 2007)
26. K.H. Nealson, D. Saffarini, "Iron and manganese in anaerobic respiration: environment significance, physiology and regulation," Annu Rev Microbiol, 48, 311-343, 1994. (Pubitemid 24334100)
27. S. Nagpal, S. Chuichulcherm, A. Livingston, L. Peeva, "Ethanol Utilization by Sulfate- Reducing Bacteria: An Experimental and Modeling Study," Biotechnol Bioeng, 70, 533-543, 2000.
28. J.T. Rosnes, T. Torsvik, T. Lien, "Spore-Forming Thermophilic Sulfate-Reducing Bacteria Isolated from North Sea Oil Field Waters," Appl Environ Microb, 57, 2302-2307, 1991.
29. 2S corrosion." Ph.D. dissertation, Ohio University, 2006.
30. M.R. Telander, R.E. Westerman, "Hydrogen Generation by Metal Corrosion in Simulated Waste Isolation Pilot Plant Environments," SAND96-2538. Albuquerque, NM: Sandia National Laboratories, 1997.
31. M. de Romero, "The Mechanism of SRB Action In MIC Based On Sulfide Corrosion And Iron Sulfide Corrosion Products," CORROSION/2005, Paper No. 05481. (Houston, TX: NACE, 2005)