Trapped interfacial redox introduces reversibility in the oxygen reduction reaction in a non-aqueous Ca(2+) electrolyte

Electrochemical investigations of the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) have been conducted in a Ca(2+)-containing dimethyl sulfoxide electrolyte. While the ORR appears irreversible, the introduction of a tetrabutylammonium perchlorate (TBAClO(4)) co-salt in excess concentrations results in the gradual appearance of a quasi-reversible OER process. Combining the results of systematic cyclic voltammetry investigations, the degree of reversibility depends on the ion pair competition between Ca(2+) and TBA(+) cations to interact with generated superoxide (O(2)(−)). When TBA(+) is in larger concentrations, and large reductive overpotentials are applied, a quasi-reversible OER peak emerges with repeated cycling (characteristic of formulations without Ca(2+) cations). In situ Raman microscopy and rotating ring-disc electrode (RRDE) experiments revealed more about the nature of species formed at the electrode surface and indicated the progressive evolution of a charge storage mechanism based upon trapped interfacial redox. The first electrochemical step involves generation of O(2)(−), followed primarily by partial passivation of the surface by Ca(x)O(y) product formation (the dominant initial reaction). Once this product matrix develops, the subsequent formation of TBA(+)--O(2)(−) is contained within the Ca(x)O(y) product interlayer at the electrode surface and, consequently, undergoes a facile oxidation reaction to regenerate O(2).