Reduction of Fe(III) colloids by Shewanella putrefaciens: A kinetic model

Bonneville, Steeve; Behrends, Thilo; Cappellen, Philippe Van; Hyacinthe, Christelle; Röling, Wilfred F. M.

doi:10.1016/j.gca.2006.04.029

Cited by 74 publications

(60 citation statements)

References 40 publications

(58 reference statements)

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“…8.15c). Previous work by Caccavo (2000, 2001), as well as a recent study by Bonneville et al (2006), revealed qualitatively similar results for the association of Fe(III) oxides with DIRM cell surfaces, and the relationship between oxide-adhered DIRM cell density and Fe(III) reduction rate. The association of DIRMs with Fe(III) oxides is probably driven by hydrophobic rather than electrostatic forces, since both DIRM cells and Fe(III) oxides bear a net negative charge at pH (Caccavo et al, 1997;Caccavo, 2000, 2001).…”

Section: Influence Of Dirm Cell Density and Association With Oxide Pasupporting

confidence: 73%

“…1 in (Caccavo, 1999;Caccavo and Das, 2002). Current evidence suggests that the latter components are required for the irreversible adhesion of Fe(III) oxides to DIRM cells (Caccavo and Das, 2002) that has been observed in several studies (Bonneville et al, 2006;Caccavo, 1999;Caccavo et al, 1996;Glasauer et al, 2001). However, irreversible adhesion is not required for enzymatic reduction to take place (Caccavo et al, 1997;Caccavo and Das, 2002;Grantham et al, 1997), and detachment and transport of DIRM cells clearly takes place in hydrologically open reaction systems Roden et al, 2000).…”

Section: Influence Of Dirm Cell Density and Association With Oxide Pamentioning

confidence: 80%

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Microbiological Controls on Geochemical Kinetics 1: Fundamentals and Case Study on Microbial Fe(III) Oxide Reduction

Roden¹

2008

Kinetics of Water-Rock Interaction

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Section: Influence Of Dirm Cell Density and Association With Oxide Pasupporting

confidence: 73%

Section: Influence Of Dirm Cell Density and Association With Oxide Pamentioning

confidence: 80%

Microbiological Controls on Geochemical Kinetics 1: Fundamentals and Case Study on Microbial Fe(III) Oxide Reduction

Roden¹

2008

Kinetics of Water-Rock Interaction

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“…It has been shown before that the iron oxide-microorganism contact area has an impact on reduction rates (3). Colloids constantly undergo Brownian movement, probably increasing their potential for capturing electrons from the cell surface by higher numbers of contact events with reactive sites at the microbial cell surface, although there is also a potential for long-term attachment of nanoparticles to iron-reducing cells (3). Another aspect might be that colloidal particles have the potential to fully cover the bacterial cell following a Langmuir isotherm (3), as opposed to bulk ferric iron phases, which probably cannot cover the cell due to a spatial limitation.…”

Section: Vol 76 2010 Nanosized Iron Oxide Colloids Enhance Iron Redmentioning

confidence: 99%

“…Naturally, well crystalline minerals have lower surface areas, and the effects of surface area and solubility cannot be distinguished sharply. Cell density, initial oxide and substrate concentrations, and ferrous iron adsorbed to the bulk mineral surface were also reported to control microbial reduction rates by exhibiting mutual saturation behavior in Michaelis-Mententype kinetics (3,22,40).…”

mentioning

confidence: 99%

Nanosized Iron Oxide Colloids Strongly Enhance Microbial Iron Reduction

Bosch

Heister

Hofmann

et al. 2010

Appl Environ Microbiol

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Microbial iron reduction is considered to be a significant subsurface process. The rate-limiting bioavailability of the insoluble iron oxyhydroxides, however, is a topic for debate. Surface area and mineral structure are recognized as crucial parameters for microbial reduction rates of bulk, macroaggregate iron minerals. However, a significant fraction of iron oxide minerals in the subsurface is supposed to be present as nanosized colloids. We therefore studied the role of colloidal iron oxides in microbial iron reduction. In batch growth experiments with Geobacter sulfurreducens, colloids of ferrihydrite (hydrodynamic diameter, 336 nm), hematite (123 nm), goethite (157 nm), and akaganeite (64 nm) were added as electron acceptors. The colloidal iron oxides were reduced up to 2 orders of magnitude more rapidly (up to 1,255 pmol h ؊1 cell ؊1 ) than bulk macroaggregates of the same iron phases (6 to 70 pmol h ؊1 cell ؊1 ). The increased reactivity was not only due to the large surface areas of the colloidal aggregates but also was due to a higher reactivity per unit surface. We hypothesize that this can be attributed to the high bioavailability of the nanosized aggregates and their colloidal suspension. Furthermore, a strong enhancement of reduction rates of bulk ferrihydrite was observed when nanosized ferrihydrite aggregates were added.

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“…Reduced conditions are maintained in water-logged soils and sediments due to back-consumption of oxygen and organic carbon by chemotrophic microorganisms. The rate of Fe(II) production by micro-organisms depends on the surface area of the ferric (hydr)oxide that is in contact with micro-organisms (Bonneville et al, 2006). Under intermediate redox conditions (10 < pe < 0) and neutral pH values, iron can be present as aqueous Fe(II) in combination with Fe(III) (hydr)oxides.…”

Section: Introductionmentioning

confidence: 99%