Quantum chemical modeling of tri-Mn-substituted W-based Keggin polyoxoanions

- DFT modeling of electrochemistry of tri-Mn substituted Keggin ions.
- Reversible half-wave redox potentials modeled.
- pH dependence of Mn(IV/III) redox reproduced.
- Description of electrolyte environment of POMs found to be crucially important.
- Mn(III/II) redox process more sensitive to electrolyte description than Mn(IV/III).

Using Density Functional Theory (DFT) calculations, we studied the electrochemistry of polyoxometalates (POMs), specifically the redox properties of Mn in tri-Mn-substituted W-based Keggin ions. For direct comparison with recent cyclic voltammetry results [J. Friedl et al. Electrochim. Acta, 141 (2014) 357], we estimated the reversible half-wave potentials of proton- and cation-coupled electron transfer for Mn(IV/III) and Mn(III/II), respectively. The calculated reversible potentials agree well with experiment, reproducing the trend with pH for Mn(IV/III). For adequate DFT energies, it is crucial to apply a reliable description of the electrolyte environment of the POM, accounting also for their rather high charges, up to −7 e. To this end, we included the Li+ counterions, required for charge neutralization, directly in the quantum chemical models which were embedded in a polarizable continuum. We explored various arrangements of the Li+ ions around the POMs and their effect on both structural parameters and electrochemical properties of the POMs. Hybrid functionals (TPSSh, B3LYP, PBE0) overestimate the experimental reduction potentials: the larger the exact-exchange contribution, the larger the resulting reduction potential. The best agreement with experiment is achieved with the PBE approach, likely due to fortuitous error cancellation. The results of the present work indicate that a more sophisticated (atomistic) representation of the electrolyte environment will be beneficial for predicting redox potentials in better agreement with experiment.

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