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This investigation reports on the growth of this bacterial species on the …

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- The effect of adsorbed lipid on pyrite oxidation under biotic conditions

  1. Santelli CM, Welch SA, Westrich HR, Banfield JF: The effect of Fe-oxidizing bacteria on Fe-silicate mineral dissolution.

    Chemical Geology 2001, 180:99-115

  2. Chakrabarti BK, Banerjee PC: Surface hydrophobicity of acidophilic heterotrophic bacterial cells in relation to their adhesion on minerals.

    Canadian Journal of Microbiology 1991, 37:692-696.

  3. Southam G, Beveridge TJ: Enumeration of thiobacilli within pH-neutral and acidic mine tailings and their role in the development of secondary mineral soil.

    Applied and Environmental Microbiology 1992, 58:1904-1912. 

  4. Dziurla M-A, Achouak W, Lam B-T, Heulin T, Berthelin J: Enzyme-linked immunofiltration assay to estimate attachment of thiobacilli to pyrite.

    Applied and Environmental Microbiology 1998, 64:2937-2942.

  5. Ohmura N, Kitamura K, Saiki H: Selective adhesion of Thiobacillus ferrooxidans to pyrite.

    Applied and Environmental Microbiology 1993, 59:4044-4050.

  6. Lawrence JR, Kwong YTJ, Swerhone GDW: Colonization and weathering of natural sulfide mineral assemblages by Thiobacillus ferrooxidans.

    Canadian Journal of Microbiology 1997, 43:178-188. 

  7. Edwards KJ, Schrenk MO, Hamers R, Banfield JF: Microbial oxidation of pyrite: experiments using microorganisms from an extreme acidic environment.

    American Mineralogist 1998, 83:1444-1453

  8. Sand W, Gerke T, Hallmann R, Schippers A: Sulfur chemistry, biofilm, and the (in)direct attack mechanism – a critical evaluation of bacterial leaching.

    Applied Microbiology and Biotechnology 1995, 43:961-966. 

  9. Wakao N, Mishina M, Sakurai Y, Shiota H: Bacterial pyrite oxidation. III. Adsorption of Thiobacillus ferrooxidans cells on solid surfaces and its effect on iron release from pyrite.

    Journal of General and Applied Microbiology 1984, 30:63-77.

  10. Edwards KJ, Bond PL, Banfield JF: Characteristics of attachment and growth of Thiobacillus caldus on sulfide minerals: a chemotactic response to sulfur minerals?

    Environmental Microbiology 2000, 2:324-332.

  11. Mielke RE, Pace DL, Porter T, Southam G: A critical stage in the formation of acid mine drainage: colonization of pyrite by Acidithiobacillus ferrooxidans under pH-neutral conditions.

    Geobiology 2003, 1:81-90.

  12. Nordstrom DK, Southam G: Geomicrobiology of sulfide mineral oxidation.

    Reviews in Mineralogy 1997, 35:361-390.

  13. Gleisner M, Herbert RB, Frogner Kockum PC: Pyrite oxidation by Acidithiobacillus ferrooxidans at various concentrations of dissolved oxygen.

    Chemical Geology 2006, 225:16-29. 

  14. Elsetinow AR, Borda MJ, Schoonen MAA, Strongin DR: Suppression of pyrite oxidation in acidic aqueous environments using lipids having two hydrophobic tails.

    Advances in Environmental Research 2003, 7:969-974.

  15. Zhang X, Borda MJ, Schoonen MAA, Strongin DR: Adsorption of phospholipids on pyrite and their effect on surface oxidation.

    Langmuir 2003, 19:8787-8792.

  16. Zhang X, Borda MJ, Schoonen MAA, Strongin DR: Pyrite oxidation inhibition by a cross-linked lipid coating.

    Geochemical Transactions 2003, 4:8-11

  17. Elsetinow AR, Schoonen MAA, Strongin DR: Aqueous geochemical and surface science investigation of the effect of phosphate on pyrite oxidation.

    Environmental Science and Technology 2001, 35:2252-2257.

  18. Muyer G, de Bruyn JC, Schmedding DJM, Bos P, Westbroek P, Kuenen JG: A combination immunofluorescence-DNA-fluorescence staining technique for enumeration of Thiobacillus ferrooxidans in a population of acidophilic bacteria.

    App Environ Microbiol 1987, 53:660-664.

  19. Sherr BF, Sherr EB, del Giorgio P: Enumeration of total and highly active bacteria. In Marine Microbiology. Volume 30. Edited by: Paul J. London: Academic Press; 2001:129-159. 

  20. Silverman MP: Mechanism of bacterial pyrite oxidation.

    Journal of Bacteriology 1967, 94:1046-1051. 

  21. Singer PC, Stumm W: Acid mine drainage: the rate-limiting step.

    Science 1970, 167:1121-1123.

  22. Moses CO, Herman JS: Pyrite oxidation at circumneutral pH.

    Geochimica et Cosmochimica Acta 1991, 55:471-482. 

  23. Schoonen M, Elsetinow A, Borda M, Strongin D: Effect of temperature and illumination on pyrite oxidation between pH 2 and 6.

    Geochem Trans 2000.

    No pp. given, Article No. 4

  24. Olson GJ: Rate of pyrite bioleaching by Thiobacillus ferrooxidans: results of an interlaboratory comparison.

    Applied and Environmental Microbiology 1991, 57:642-644.

  25. Yu JY, McGenity TJ, Coleman ML: Solution chemistry during the lag phase and exponential phase of pyrite oxidation by Thiobacillus ferrooxidans.

    Chemical Geology 2001, 175:307-317. 

  26. Edwards KJ, Goebel BM, Rodgers TM, Schrenk MO, Gihring TM, Cardona MM, Hu B, McGuire MM, Hamers RJ, Pace NR, Banfield JF: Geomicrobiology of pyrite (FeS2) dissolution: case study at Iron Mountain, California.

    Geomicrobiology Journal 1999, 16:155-179.

  27. Pace DL, Mielke RE, Southam G, Porter TL: Scanning Force Microscopy Studies of the Colonization and Growth of A. ferrooxidans on the Surface of Pyrite Minerals.

    Scanning 2005, 27:136-140.

  28. Zhang XV, Kendall TA, Hao J, Strongin DR, Schoonen MAA, Martin ST: Physical structures of lipid layers on pyrite.

    Environmental Science and Technology 2006, 40(5):1511-1515. 

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