Density Functional Theory Modeling of the Oxidation Mechanism of Tl(I) by Birnessite

Manceau, Alain; Steinmann, Stephan N.

doi:10.1021/acsearthspacechem.3c00103

ACS Earth Space Chem.

2023

DOI: 10.1021/acsearthspacechem.3c00103

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Density Functional Theory Modeling of the Oxidation Mechanism of Tl(I) by Birnessite

Alain Manceau

Stephan N. Steinmann

Abstract: This study establishes a theoretical foundation for the oxidation pathway of monovalent thallium (Tl(I)) to trivalent thallium (Tl(III)) on birnessite, which is responsible for the over million-times enrichment of Tl in marine ferromanganese deposits over seawater concentration. Tl(I) oxidation occurs on vacant Mn(IV) sites located on the basal planes of the birnessite layers and on the edge sites, in agreement with experiment. Two Mn(IV) atoms are reduced to Mn(III) when Tl(I) gives up two electrons in two on… Show more

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Cited by 2 publications

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Layer-to-tunnel manganese oxides transformation triggered by pyrogenic carbon and trace metals: Key role of reducing and oxidizing components cooperation

Xu,

Ma,

Tang

et al. 2025

Geochimica et Cosmochimica Acta

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Layer-to-tunnel manganese oxides transformation triggered by pyrogenic carbon and trace metals: Key role of reducing and oxidizing components cooperation

Xu,

Ma,

Tang

et al. 2025

Geochimica et Cosmochimica Acta

View full text Add to dashboard Cite

Elucidating Details of the Transformation of Birnessite into a Tunnel Structure in the Presence of Tl(I)

Martínez,

Pi-Puig,

Villalobos

2024

ACS Earth Space Chem.

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The affinity between highly toxic Tl + and birnessite has been a matter of active research because the sorption mechanism involved seems to depend upon the doses of applied Tl + per Mn present, which also affects how birnessite is transformed. Aqueous Tl + is very mobile; therefore, its transformation and strong immobilization by Mn oxides is of high interest for environmental research. Birnessites are laminar Mn oxides that show a complex sorption behavior, which involves binding to internal sites of the structure and external surface groups and a high oxidation potential. In the present short investigation, we report some important issues not resolved over the mechanism involved when small Tl + /Mn interacts, in which the laminar structure changes to a tunneled structure. Specifically, because very little Tl + is oxidized (as opposed to when higher ratios are involved), water was experimentally confirmed as the reducing agent and the probable mechanism involved was theoretically worked out. Also, the irreversible nature of Tl(I) sorption inside the transformed tunneled structure was tested, which confirmed the extremely high affinity of the Mn oxide tunnels for dehydrated Tl(I).

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Density Functional Theory Modeling of the Oxidation Mechanism of Tl(I) by Birnessite

Cited by 2 publications

References 55 publications

Layer-to-tunnel manganese oxides transformation triggered by pyrogenic carbon and trace metals: Key role of reducing and oxidizing components cooperation

Layer-to-tunnel manganese oxides transformation triggered by pyrogenic carbon and trace metals: Key role of reducing and oxidizing components cooperation

Elucidating Details of the Transformation of Birnessite into a Tunnel Structure in the Presence of Tl(I)

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