Litcius/Paper detail

Tuning Oxygen Reduction Catalysis of Dinuclear Cobalt Polypyridyl Complexes by the Bridging Structure

Hiroaki Arima, Misato Wada, Takashi Nakazono, Tohru Wada

2021Inorganic Chemistry25 citationsDOI

Abstract

The four-electron oxygen reduction reaction (4e–-ORR) is the mainstay in chemical energy conversion. Elucidation of factors influencing the catalyst’s reaction rate and selectivity is important in the development of more active catalysts of 4e–-ORR. In this study, we investigated chemical and electrochemical 4e–-ORR catalyzed by Co2(μ-O2) complexes bridged by xanthene (1) and anthracene (3) and by a Co2(OH)2 complex bridged by anthraquinone (2). In the chemical ORR using Fe(CpMe)2 as a reductant in acidic PhCN, we found that 1 showed the highest initial turnover frequency (TOFinit = 6.8 × 102 s–1) and selectivity for 4e–-ORR (96%) in three complexes. The detailed kinetic analyses have revealed that the rate-determining steps (RDSs) in the catalytic cycles of 1–3 have the O2 addition to [CoII2(OH2)2]4+ as an intermediate in common. In the only case that complex 1 was used as a catalyst, kcat depended on proton concentration because the reaction rate of the O2 addition to [CoII2(OH2)2]4+ was so fast as compared to that of the concerted PCET process of 1. Through X-ray, Raman, and electrochemical analyses and stoichiometric reactions, we found the face-to-face structure of 1 characterized by a slightly flexible xanthene was advantageous in capturing O2 and stabilizing the Co2(μ-O2) structure, thus increasing both the reaction rate and selectivity for 4e–-ORR.

Topics & Concepts

ChemistryCatalysisXantheneSelectivityElectrochemistryStoichiometryAnthraquinoneElectron transferRedoxCobaltReaction rateInorganic chemistryReaction rate constantPhotochemistryKineticsPhysical chemistryOrganic chemistryElectrodeQuantum mechanicsPhysicsElectrocatalysts for Energy ConversionAdvanced battery technologies researchCO2 Reduction Techniques and Catalysts
Tuning Oxygen Reduction Catalysis of Dinuclear Cobalt Polypyridyl Complexes by the Bridging Structure | Litcius