Synthesis and Structure of an Ion‐Exchanged SrTiO₃ Photocatalyst with Improved Reactivity for Hydrogen Evolution

Abstract BaTiO 3 heated in an excess of SrCl 2 at 1150 °C converts to SrTiO 3 through an ion exchange reaction. The SrTiO 3 synthesized by ion exchange produces hydrogen from pH 7 water at a rate more than twice that of conventional SrTiO 3 treated identically. The apparent quantum yield for hydrogen production in pure water of the ion exchanged SrTiO 3 is 11.4% under 380 nm illumination. The catalyst resulting from ion‐exchange differs from conventional SrTiO 3 by having ≈2% residual Ba, inhomogeneous Cl‐doping at a concentration less than 1%, Kirkendall voids in the centers of particles that result from the unequal rates of Sr and Ba diffusion together with the transport of Ti and O, and nanoscale regions near the surface that have lattice spacings consistent with the Sr‐excess phase Sr 2 TiO 4 . The increased photochemical efficiency of this nonequilibrium structure is most likely related to the Sr‐excess, which is known to compensate donor defects that can act as charge traps and recombination centers.