Effects of pH and Ca exchange on the structure and redox state of synthetic Na-birnessite

Birnessite-like minerals are among the most common Mn oxides in surficial soils and sediments, and they mediate important environmental processes (e.g., biogeochemical cycles, heavy metal confinement) and have novel technological applications (e.g., water oxidation catalysis). Ca is the dominant interlayer cation in both biotic and abiotic birnessites, especially when they form in association with carbonates. The current study investigated the structures of a series of synthetic Ca-birnessite analogs prepared by cation-exchange with synthetic Na-birnessite at pH values from 2 to 7.5. The resulting Ca-exchanged birnessite phases were characterized using powder X-ray diffraction and Rietveld refinement, Fourier transform infrared spectroscopy, Raman spectroscopy, X-ray photoelectron spectroscopy, and scanning and transmission electron microscopy. All samples synthesized at pH values greater than 3 exhibited a similar triclinic structure with nearly identical unit-cell parameters. The samples exchanged at pH 2 and 3 yielded hexagonal structures, or mixtures of hexagonal and triclinic phases. Rietveld structure refinement and X-ray photoelectron spectroscopy showed that exchange of Na by Ca triggered reduction of some Mn3+, generating interlayer Mn2+ and vacancies in the octahedral layers. The triclinic and hexagonal Ca-birnessite structures described in this study were distinct from Na-and H-birnessite, respectively. Therefore, modeling X-ray absorption spectra of natural Ca-rich birnessites through mixing of Na-and H-birnessite end-members will not yield an accurate representation of the true structure.



Work Title Effects of pH and Ca exchange on the structure and redox state of synthetic Na-birnessite
Open Access
  1. Chiara Elmi
  2. Jeffrey E. Post
  3. Peter J. Heaney
  4. Eugene S. Ilton
License In Copyright (Rights Reserved)
Work Type Article
  1. American Mineralogist
Publication Date January 27, 2021
Publisher Identifier (DOI)
  1. https://doi.org/10.2138/am-2020-7112
Deposited December 01, 2021




This resource is currently not in any collection.

Work History

Version 1

  • Created
  • Added Elmi_CaBirn_AmMin_2021.pdf
  • Added Creator Chiara Elmi
  • Added Creator Jeffrey E. Post
  • Added Creator Peter J. Heaney
  • Added Creator Eugene S. Ilton
  • Published
  • Updated
  • Updated