Different isotope and chemical patterns of pyrite oxidation related to lag and exponential growth phases of Acidithiobacillus ferrooxidans reveal a microbial growth strategy

Autor: Randall E. Mielke, Terry J. McGenity, Stojan Madzunkov, J. A. MacAskill, Benjamin Brunner, Max Coleman, Jae Young Yu
Rok vydání: 2008
Předmět:
Zdroj: Earth and Planetary Science Letters. 270:63-72
ISSN: 0012-821X
Popis: The solution chemistry during the initial (slow increase of dissolved iron and sulfate) and main stage (rapid increase of dissolved iron and sulfate) of pyrite leaching by Acidithiobacillus ferrooxidans ( Af ) at a starting pH of 2.05 shows significant differences. During the initial stage, ferrous iron (Fe 2+ ) is the dominant iron species in solution and the molar ratio of produced sulfate (SO 4 2− ) and total iron (Fe tot ) is 1.1, thus does not reflect the stoichiometry of pyrite (FeS 2 ). During the main stage, ferric iron (Fe 3+ ) is the dominant iron species in solution and the SO 4 2− :Fe tot ratio is with 1.9, close to the stoichiometry of FeS 2 . Another difference between initial and main stage is an initial trend to slightly higher pH values followed by a drop during the main stage to pH 1.84. These observations raise the question if there are different modes of bioleaching of pyrite, and if there are, what those modes imply in terms of leaching mechanisms. Different oxygen and sulfur isotope trends of sulfate during the initial and main stages of pyrite oxidation confirm that there are two pyrite bioleaching modes. The biochemical reactions during initial stage are best explained by the net reaction FeS 2 + 3O 2 ⇒ Fe 2+ + SO 4 2− + SO 2 (g). The degassing of sulfur dioxide (SO 2 ) acts as sink for sulfur depleted in 34 S compared to pyrite, and is the cause of the SO 4 2− :Fe tot ratio of 1.1 and the near constant pH. During the exponential phase, pyrite sulfur is almost quantitatively converted to sulfate, according to the net reaction FeS 2 + 15/4O 2 + 1/2H 2 O ⇒ Fe 3+ + 2SO 4 2− + H + . We hypothesize that the transition between the modes of bioleaching of pyrite is due to the impact of the accumulation of ferrous iron, which induces changes in the metabolic activity of Af and may act as an inhibitor for the oxidation of sulfur species. This transition defines a fundamental change in the growth strategy of Af . A mode, where bacteria gain energy by oxidation of elemental sulfur to sulfite but show little growth is switched into a mode, where bacteria gain a smaller amount of energy by the oxidation of ferrous iron, but induce much faster pyrite leaching rates due to the production of ferric iron.
Databáze: OpenAIRE
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