The Effects of Gamma (γ-) Sterilization on the Redox Stability, Minerology, and Physicochemical Properties of the Synthetic Iron Oxides Ferrihydrite, Lepidocrocite, and Goethite

Khan, Brandon Sajad

January 2017

Laboratory analyses were conducted on synthetic iron oxides to assess the use of gamma (γ-) irradiation as an efficient sterilization technique to remove microorganisms present in natural bacteriogenic iron oxides (BIOS) and to determine if the technique induces mineralogical changes within the Fe-rich minerals. Fe-oxides (ferrihydrite, lepidocrocite, and goethite) were synthesized with and without alginate (as a proxy for exopolysaccharides) and microbial reductions were carried out using the bacterium Shewanella putrefaciens CN32. A total of 18 Fe-oxide minerals were subjected to microbial reduction to assess redox stability, alteration due to varying levels of gamma irradiation (0, 5, and 28 kGy), and the addition of the exopolysaccharide alginate. Iron reduction rates varied for each Fe-oxide with faster Fe (III) reduction rates observed for the amorphous poorly-sorted 2-line ferrihydrite and slower Fe (III) reduction for the more crystalline Fe-oxides lepidocrocite and goethite. There was no significant impact to the Fe (III) reduction rates due to gamma irradiation (p> 0.05), which was confirmed using a t-test for statistical variance between gamma irradiated samples. However, the addition of alginate enabled lepidocrocite and goethite to achieve maximum Fe (III) reduction by an average of 7 days faster when compared to the Fe-oxides synthesized without the exopolysaccharide.

BIOS

Fe-oxides

Sterilization

Alginate

Effects of carbon during Fe(II)-catalyzed Fe oxide recrystallization: implications for Fe and carbon cycling

Pasakarnis, Timothy Stephen

01 July 2013

The reaction between aqueous Fe(II) and Fe(III) oxides is extremely complex, and can catalyze Fe(II)-Fe(III) electron transfer, exchange of Fe atoms between the aqueous and solid phases, mineral transformation, and contaminant reduction. Together, these processes represent a phenomenon referred to as Fe(II)-catalyzed Fe oxide recrystallization, which has been observed under controlled conditions in the laboratory for numerous Fe oxides. In the environment, Fe oxides are likely surrounded by organic carbon in various forms, but their potential to interfere with Fe(II)-catalyzed Fe oxide recrystallization, and its subsequent environmental relevance has not been well studied. The Fe(II)-catalyzed recrystallization of stable Fe oxides goethite and magnetite was studied in the presence of several environmentally relevant classes of organic carbon. For both goethite and magnetite, Fe(II)-catalyzed recrystallization continued relatively undeterred in the presence of electron shuttling compounds, natural organic matter isolates, and extracellular polysaccharides. Slight inhibition was observed when spent media from dissimilatory iron-reducing cultures was present, but only by sorbing a long-chain phospholipid to the oxides was significant inhibition observed. The lack of interference by organic carbon indicates that Fe(II)-catalyzed Fe oxide recrystallization is likely to be relevant throughout a wide range of environments, and represents a significant process with regards to the geochemical cycling of Fe atoms, a claim supported by evidence of Fe(II)-driven isotope mixing in real soils. The movement of atoms during Fe(II)-catalyzed Fe oxide recrystallization is not limited to just Fe however. Multiple trace elements have been shown to exchange between the aqueous and solid phases along with Fe during the Fe(II)-catalyzed recrystallization of Fe oxides. The effect of organic carbon, both sorbed to the oxide surface and coprecipitated with the oxide, on Fe(II)-catalyzed atom exchange and transformation of ferrihydrite was studied. Again, the presence of organic carbon did not appear to influence Fe atom exchange kinetics. It also did not appear to influence the rapid transformation of ferrihydrite to lepidocrocite. The presence of organic carbon does appear to ultimately have implications for mineral transformation, as over longer time periods it stabilized lepidocrocite, preventing its subsequent transformation to magnetite or goethite.

Carbon

Fe(II)

Fe oxides

Mercury

Recrystallization

Redox chemistry

Civil and Environmental Engineering

Lead and arsenic speciation and bioaccessibility following sorption on oxide mineral surfaces

Beak, Douglas Gerald

22 November 2005

No description available.

Arsenic

Lead

bioaccessibility

bioavailability

Fe oxides

Al Oxides

Mn Oxides

Ferrihydrite

Corundum

Birnessite

As Speciation

Pb Speciation

EXAFS

XANES