Abstract
A coupled oxygen evolution mechanism (COM) during oxygen evolution reaction (OER) has been reported in nickel oxyhydroxides (NiOOH)-based materials by realizing e(g)(*) band (3d electron states with e(g) symmetry) broadening and light irradiation. However, the link between the e(g)(*) band broadening extent and COM-based OER activities remains unclear. Here, Ni(1-x)Fe(x)OOH (x = 0, 0.05, 0,2) are prepared to investigate the underlying mechanism governing COM-based activities. It is revealed that in low potential region, realizing stronger e(g)(*) band broadening could facilitate the (*)OH deprotonation. Meanwhile, in high potential region where the photon utilization is the rate-determining step, a stronger e(g)(*) band broadening would widen the non-overlapping region between d(z)(2) and a(1g)(*) orbitals, thereby enhancing photon utilization efficiency. Consequently, a stronger e(g)(*) band broadening could effectuate more efficient OER activities. Moreover, we demonstrate the universality of this concept by extending it to reconstruction-derived X-NiOOH (X = NiS(2), NiSe(2), Ni(4)P(5)) with varying extent of e(g)(*) band broadening. Such an understanding of the COM would provide valuable guidance for the future development of highly efficient OER electrocatalysts.