Flux Synthesis of Na2Ca2Nb4O13: The Influence of Particle Shapes, Surface Features, and Surface Areas on Photocatalytic Hydrogen Production

The layered perovskite (n=4) Ruddlesden-Popper phase Na2Ca2Nb4O13 was prepared within molten NaCl and Na2SO4 fluxes, yielding either rod-shaped or platelet-shaped particles, respectively. The flux-to-reactant molar ratios of 5:1 or 20:1 were found to significantly influence particle sizes and surface areas, while still maintaining the overall particle shapes. Measured surface areas of flux-prepared Na2Ca2Nb4O13 particles ranged from approximate to 0.36 to 4.6m2/g, with the highest surface areas obtained using a 5:1 (NaCl-to-Na2Ca2Nb4O13) molar ratio. All samples exhibited a bandgap size of approximate to 3.3eV, as determined by UVVis diffuse reflectance measurements. Photocatalytic rates for hydrogen production under ultraviolet light for platinized Na2Ca2Nb4O13 particles in an aqueous methanol solution ranged from approximate to 230 to 1355molH2g1h1 when using the photochemical deposition (PCD) method of platinization, and approximate to 1131099molH2g1h1 when using the incipient wetness impregnation (IWI) method of platinization. The higher photocatalytic rates were obtained for the rod-shaped particles with the highest surface areas, with an apparent quantum yield (AQY) measured at approximate to 6.5% at 350nm. For the platelet-shaped particles, the higher photocatalytic rates were observed for the sample with the lowest surface area but the largest concentration of stepped edges and grooves observed at the particle surfaces. The latter origin of the photocatalytic activity is confirmed by the significant enhancement of the photocatalytic rates by the PCD method that allows for the preferential deposition of the surface Pt cocatalyst islands at the stepped edges and grooves, while the photocatalytic enhancement is much smaller when using the more general IWI platinization method.