Temperature-dependent electronic structure of bixbyite α-Mn(2)O(3) and the importance of a subtle structural change on oxygen electrocatalysis

Bixbyite [Image: see text] -Mn(2)O(3) is an inexpensive Earth-abundant mineral that can be used to drive both oxygen evolution (OER) and oxygen reduction reactions (ORR) in alkaline conditions. It possesses a subtle orthorhombic [Image: see text] cubic phase change near room temperature that suppresses Jahn–Teller distortions and presents a unique opportunity to study how atomic structure affects the electronic structure and catalytic activity at a temperature range that is easily accessible in OER/ORR experiments. Previously, we observed that heat-treated [Image: see text] -Mn(2)O(3) had a better performance as a bifunctional catalyst in the oxygen evolution (OER) and oxygen reduction reactions (ORR) (Dalton Trans. 2016, 45, 18,494–18,501). We hypothesized that heat-treatment pinned the material into a more electrochemically active cubic phase. In this manuscript, we use high-resolution X-ray diffraction to collect the temperature-dependent structures of [Image: see text] -Mn(2)O(3), and then input them into ab initio calculations. The electronic structure calculations indicate that the orthorhombic [Image: see text] cubic phase transition causes the Mn 3d and O 2p bands to overlap and mix covalently, transforming [Image: see text] -Mn(2)O(3) from a semiconductor to a semimetal. This subtle change in structure also modifies Mn-O-Mn bond distances, which may improve the activity of the material in oxygen electrochemistry. OER and ORR experiments were performed using the same electrode at various temperatures. They show a jump in the exchange current density near the phase change temperature, demonstrating the higher activity of the cubic phase.