2D Ca/Nb-based perovskite oxide with Ta doping as highly efficient H2O2 synthesis catalyst

Perovskite oxides (POs) are emerging as a class of highly efficient catalysts for reducing oxygen to H2O. Although a rich variety of POs-based catalysts have been developed by tuning the complex composition, a highly efficient PO catalyst that is able to alter the reaction pathway from a 4e(-) process to a 2e(-) process for H2O2 production has rarely been achieved. We modified the structure and composition of a Ca- and Nb-based PO material by realizing a uniform two-dimensional (2D) morphology and varied Ta doping, resulting in the 2D Ca(2)Nb(3-x)TaxO(10)- (x = 0, 0.5, 1, and 1.5) monolayer catalysts. The obtained catalysts exhibit a dominant 2e(-) pathway and show exceptional H2O2 production efficiency. The typical Ca2Nb2.5Ta0.5O10- nanoflakes showed an onset potential of 0.735 V vs. reversible hydrogen electrode (RHE), a remarkably high selectivity over 95% across a wide range of 0.3-0.7 V, an impressively high Faradaic efficiency of 94%, and a notable H2O2 productivity of 1571 mmol.gcat(-1).h(-1). These findings highlight the great potential of 2D perovskite oxide nanoflakes as advanced electrocatalysts for 2e(-) oxygen reduction reaction.