Metal Adsorption Controls Stability of Layered Manganese Oxides

Hexagonal birnessite, a typical layered Mn oxide (LMO), can adsorb and oxidize Mn­(II) and thereby transform to Mn­(III)-rich hexagonal birnessite, triclinic birnessite, or tunneled Mn oxides (TMOs), remarkably changing the environmental behavior of Mn oxides. We have determined the effects of coexi...

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Bibliographic Details
Published in:Environmental science & technology 2019-07, Vol.53 (13), p.7453-7462
Main Authors: Yang, Peng, Post, Jeffrey E, Wang, Qian, Xu, Wenqian, Geiss, Roy, McCurdy, Patrick R, Zhu, Mengqiang
Format: Article
Language:English
Subjects:
Adsorption
Anoxic conditions
Bearing
Calcium chloride
Calcium ions
Cations
Control stability
Copper
Environmental behavior
Environmental changes
GEOSCIENCES
Heavy metals
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Magnesium
Manganese
Manganese dioxide
Manganese oxides
Metal ions
Metals
Minerals
Oxides
Sodium
Surface chemistry
Surface energy
Surface properties
Surface stability
Transition metals
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Summary:Hexagonal birnessite, a typical layered Mn oxide (LMO), can adsorb and oxidize Mn­(II) and thereby transform to Mn­(III)-rich hexagonal birnessite, triclinic birnessite, or tunneled Mn oxides (TMOs), remarkably changing the environmental behavior of Mn oxides. We have determined the effects of coexisting cations on the transformation by incubating Mn­(II)-bearing δ-MnO2 at pH 8 under anoxic conditions for 25 d (dissolved Mn < 11 μM). In the Li+, Na+, and K+ chloride solutions, the Mn­(II)-bearing δ-MnO2 first transforms to Mn­(III)-rich δ-MnO2 or triclinic birnessite (T-bir) due to the Mn­(II)–Mn­(IV) comproportionation, most of which eventually transform to a 4 × 4 TMO. In contrast, Mn­(III)-rich δ-MnO2 and T-bir form and persist in the Mg2+ and Ca2+ chloride solutions. However, in the presence of surface adsorbed Cu­(II), Mn­(II)-bearing δ-MnO2 turns into Mn­(III)-rich δ-MnO2 without forming T-bir or TMOs. The stabilizing power of the cations on the δ-MnO2 structure positively correlates with their binding strength to δ-MnO2 (Li+, Na+, and K+ < Mg2+ and Ca2+ < Cu­(II)). Since metal adsorption decreases the surface energy of minerals, our finding suggests that the surface energy largely controls the thermodynamic stability of LMOs. Our study indicates that the adsorption of divalent metal cations, particularly transition metals, can be an important cause of the high abundance of LMOs, rather than the more stable TMO phases, in the environment.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.9b01242