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Geochemical modeling of bacterially induced mineralization of schwertmannite and jarosite in sulfuric acid spring water

  • Motoharu Kawano EMAIL logo and Katsutoshi Tomita
Published/Copyright: March 26, 2015
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American Mineralogist
From the journal American Mineralogist Volume 86 Issue 10

Abstract

Mineralogy and geochemistry of a sulfuric acid spring water with a pH of 3.37 to 2.89 were investigated to verify the formation processes of iron minerals and the effects of bacteria on their formation. To estimate the solubility of schwertmannite, experimental dissolution in 10.0 mM H2SO4 was conducted and this solubility data was used for geochemical modeling. Experimental incubation of the spring water containing bacteria was also performed and compared with a simulated abiotic system to evaluate the role of bacteria in the mineral formation. The spring water seeps through cracks of hydrothermally altered andesitic rocks containing pyrite, and precipitates schwertmannite and jarosite. Schwertmannite appears as a film-like thin layer floating on the water surface and composed of aggregates of spherical particles with diameters of 1 to 5 µm. Jarosite is produced as a precipitate on submerged rock surfaces. The precipitate contains well crystallized jarosite spheres 5 to 10 µm in diameter. Some ellipsoidal to rod shaped bacteria covered or decorated by poorly ordered iron minerals are also present in close association with the schwertmannite spheres. Results of the experimental incubation demonstrate that the oxidation rates of Fe2+ are 5.3 × 103 to 7.2 × 103 times greater than those of the simulated abiotic system, suggesting that the formation of the iron minerals is promoted by bacterial oxidation of Fe2+. The dissolution experiment indicates that the solubility product of the schwertmannite having an average chemical composition of Fe8O8(OH)5.9(SO4)1.05 is approximately log KS = 7.06 ± 0.09. Using this data, geochemical modeling reveals that the spring water is supersaturated with respect to schwertmannite and also goethite and jarosite, but undersaturated with respect to ferrihydrite. Additionally, it is confirmed that the bulk solution chemistry deviates slightly into the stability field of goethite rather than jarosite. This suggests that the aquatic environments in contact with the rock surfaces may be more acidic and/or enriched in SO42- relative to the bulk solution, which may eventually lead to the formation of jarosite instead of goethite.

Received: 2001-2-2
Accepted: 2001-6-15
Published Online: 2015-3-26
Published in Print: 2001-10-1

© 2015 by Walter de Gruyter Berlin/Boston

Articles in the same Issue

  1. Recalibration of the GASP geobarometer in light of recent garnet and plagioclase activity models and versions of the garnet-biotite geothermometer
  2. Compositional zoning and element partitioning in nickeloan tourmaline from a metamorphosed karstbauxite from Samos, Greece
  3. Occurrence of apatite associated with magnetite in an ophiolite complex (Othrys), Greece
  4. Overpressures induced by coesite-quartz transition in zircon
  5. Geochemical modeling of bacterially induced mineralization of schwertmannite and jarosite in sulfuric acid spring water
  6. H2O-D2O exchange in lawsonite
  7. Composition and temperature dependence of cation ordering in Ni-Mg olivine solid solutions: a time-of-flight neutron powder diffraction and EXAFS study
  8. Thermal conductivity of spinels and olivines from vibrational spectroscopy: Ambient conditions
  9. Elasticity of six polycrystalline silicate garnets at pressure up to 3.0 GPa
  10. The crystal chemistry of birefringent natural uvarovites: Part I. Optical investigations and UV-VIS-IR absorption spectroscopy
  11. The crystal chemistry of birefringent natural uvarovites: Part II. Single-crystal X-ray structures
  12. Ferroanthophyllite in Rockport grunerite: A transmission electron microscopy study
  13. Crystal structure of a new (21)-clinopyribole synthesized at high temperature and pressure
  14. The Mg(Fe)SiO3 orthoenstatite-clinoenstatite transitions at high pressures and temperatures determined by Raman-spectroscopy on quenched samples
  15. Raman spectroscopic studies of phase E to 19 GPa
  16. The crystal structures of the low-temperature phases of leonite-type compounds, K2Me(SO4)2·4H2O (Me2+ = Mg, Mn, Fe)
  17. Carraraite and zaccagnaite, two new minerals from the Carrara marble quarries: their chemical compositions, physical properties, and structural features
  18. Pristine surface growth features on 100 Ma garnet phenocrysts: Interference imaging results
  19. Oxygen triclusters in crystalline CaAl4O7 (grossite) and in calcium aluminosilicate glasses: 17O NMR
  20. Low-temperature heat capacity of pentlandite
  21. Calcium segregation at antiphase boundaries in pigeonite
https://doi.org/10.2138/am-2001-1005

Articles in the same Issue

  1. Recalibration of the GASP geobarometer in light of recent garnet and plagioclase activity models and versions of the garnet-biotite geothermometer
  2. Compositional zoning and element partitioning in nickeloan tourmaline from a metamorphosed karstbauxite from Samos, Greece
  3. Occurrence of apatite associated with magnetite in an ophiolite complex (Othrys), Greece
  4. Overpressures induced by coesite-quartz transition in zircon
  5. Geochemical modeling of bacterially induced mineralization of schwertmannite and jarosite in sulfuric acid spring water
  6. H2O-D2O exchange in lawsonite
  7. Composition and temperature dependence of cation ordering in Ni-Mg olivine solid solutions: a time-of-flight neutron powder diffraction and EXAFS study
  8. Thermal conductivity of spinels and olivines from vibrational spectroscopy: Ambient conditions
  9. Elasticity of six polycrystalline silicate garnets at pressure up to 3.0 GPa
  10. The crystal chemistry of birefringent natural uvarovites: Part I. Optical investigations and UV-VIS-IR absorption spectroscopy
  11. The crystal chemistry of birefringent natural uvarovites: Part II. Single-crystal X-ray structures
  12. Ferroanthophyllite in Rockport grunerite: A transmission electron microscopy study
  13. Crystal structure of a new (21)-clinopyribole synthesized at high temperature and pressure
  14. The Mg(Fe)SiO3 orthoenstatite-clinoenstatite transitions at high pressures and temperatures determined by Raman-spectroscopy on quenched samples
  15. Raman spectroscopic studies of phase E to 19 GPa
  16. The crystal structures of the low-temperature phases of leonite-type compounds, K2Me(SO4)2·4H2O (Me2+ = Mg, Mn, Fe)
  17. Carraraite and zaccagnaite, two new minerals from the Carrara marble quarries: their chemical compositions, physical properties, and structural features
  18. Pristine surface growth features on 100 Ma garnet phenocrysts: Interference imaging results
  19. Oxygen triclusters in crystalline CaAl4O7 (grossite) and in calcium aluminosilicate glasses: 17O NMR
  20. Low-temperature heat capacity of pentlandite
  21. Calcium segregation at antiphase boundaries in pigeonite
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