Abstract

Other| December 01, 1997 Structural mechanism of Co2+ oxidation by the phyllomanganate buserite Alain Manceau; Alain Manceau University of Grenoble, LGIT-IRIGM, Grenoble, France Search for other works by this author on: GSW Google Scholar Victor A. Drits; Victor A. Drits Search for other works by this author on: GSW Google Scholar Ewen Silvester; Ewen Silvester Search for other works by this author on: GSW Google Scholar Celine Bartoli; Celine Bartoli Search for other works by this author on: GSW Google Scholar Bruno Lanson Bruno Lanson Search for other works by this author on: GSW Google Scholar American Mineralogist (1997) 82 (11-12): 1150–1175. https://doi.org/10.2138/am-1997-11-1213 Article history first online: 02 Mar 2017 Cite View This Citation Add to Citation Manager Share Icon Share Twitter LinkedIn Tools Icon Tools Get Permissions Search Site Citation Alain Manceau, Victor A. Drits, Ewen Silvester, Celine Bartoli, Bruno Lanson; Structural mechanism of Co2+ oxidation by the phyllomanganate buserite. American Mineralogist 1997;; 82 (11-12): 1150–1175. doi: https://doi.org/10.2138/am-1997-11-1213 Download citation file: Ris (Zotero) Refmanager EasyBib Bookends Mendeley Papers EndNote RefWorks BibTex toolbar search Search nav search search input Search input auto suggest search filter All ContentBy SocietyAmerican Mineralogist Search Advanced Search Abstract The geochemistry of Co at the Earth's surface is closely associated with that of manganese oxides. This geochemical association results from the oxidation of highly soluble Co2+ to weakly soluble Co3+ species, coupled with the reduction of Mn4+ or Mn3+ ions, initially present in the manganese oxide sorbent, to soluble Mn2+. The structural mechanism of this Co immobilization-manganese oxide dissolution reaction was investigated at the buserite surface. Co-sorbed samples were prepared at different surface coverages by equilibrating a Na-exchanged buserite suspension in the presence of aqueous Co2+ at pH 4. The structure of Co-sorbed birnessite obtained by drying buserite samples was determined by X-ray diffraction (XRD) and powder and polarized EXAFS spectroscopy. For each sample we determined the proportion of interlayer cations and layer vacancy sites, the Co2+/(Co2+ + Co3+) ratio, the nature of Co sorption crystallographic sites, and the proportion of interlayer vs. layer Co. From this in-depth structural characterization two distinct oxidation mechanisms were identified that occur concurrently with the transformation of low pH monoclinic buserite to hexagonal H-rich birnessite (Drits et al. 1997; Silvester et al. 1997). The first mechanism is associated with the fast disproportionation of layer Mn3+ according to 2Mnlayer3+→Mnlayer4++□layer+Mnsolution2+⁠, where □ denotes a vacant site. Divalent Co sorbs above or below a vacant site (□1) and is then oxidized by the nearest Mnlayer3+⁠. The resulting Co3+ species fills the □1 position while the reduced Mn migrates to the interlayer or into solution creating a new vacant site (□2). This reaction can be written: Cosolution2++□1+Mnlayer3+→Cointerlayer2++□1+Mnlayer3+→Cointerlayer3++□1+Mnlayer2+→Colayer3++□2+Mnsol/inter2+⁠. This mechanism may replicate along a Mn3+-rich row, and, because the density of vacancies remains constant, it can result in relatively high Co concentrations, as well as domains rich in Colayer3+−Mnlayer4+⁠. During the low-pH buserite transformation, about one-half of the layer Mn3+ that does not disproportionate migrates from the layer to the interlayer space creating new vacancies, with the displaced Mn3+ residing above or below these vacancies. The second oxidation mechanism involves the replacement of Mninterlayer3+ by Cointerlayer3+⁠; the latter may eventually migrate into layer vacancies depending on the chemical composition of octahedra surrounding the vacancy. The criterion for the migration of Co3+ into layer vacancies is the need to avoid Mnlayer3+−Colayer3+−Mnlayer3+ sequences. The suite of chemical reactions for this second mechanism can be schematically written: Cosolution2++Mninterlayer3++□→Mnsolution2++Cointerlayer3++□→Mnsolution2++Colayer3+⁠, the last step being conditional. In contrast to the first mechanism, this second mechanism decreases the density of vacant sites. At high surface coverage, Co-sorbed birnessite contains a substantial amount of unoxidized Cointerlayer2+ species despite some non-reduced Mn3+ in the sorbent. This result can be explained by the sorption of Cosolution2+ onto vacant sites located in Colayer3+- and Mnlayer4+-rich domains devoid of Mn3+. The number and size of these domains increase with the extent of oxidation and the total Co concentration in the solution, and this accounts for the decreasing capacity of buserite to oxidize Co. The weight of structural evidence indicates that Co is oxidized by Mn3+ rather than Mn4+. Thermodynamic considerations indicate that under the solution pH conditions employed in this study Mn3+ is the more likely electron sink for the oxidation of Co2+. This study also shows that the high affinity of Co for manganese oxides is not only due to its oxidation to weakly soluble Co3+ species, but also because of the reducted layer strains from the substitution of Co3+ for Mn3+.Results obtained for these model compounds were compared with those for natural Co-containing asbolane and lithiophorite (Manceau et al. 1987). This comparison indicates that the different structural mechanisms explored in the laboratory can satisfactorily account for the observations made on natural samples. Specifically, the present study proves that Co substitutes for Mn in natural phyllomanganates and allows us to eliminate the possibility of precipitation of discrete CoOOH particles. This content is PDF only. Please click on the PDF icon to access. First Page Preview Close Modal You do not currently have access to this article.