With global warming and the energy crisis deteriorating, it is an urgent issue to develop alternative energy sources to fossil fuels. Hydrogen has been widely studied as sustainable energy with broad application potential. Moreover, the hydrogen generated by photocatalytic water splitting is known as green hydrogen, producing zero-carbon emissions. In this process, photocatalyst could absorb sunlight and decompose water into hydrogen and oxygen, i.e., convert solar energy into chemical energy. In this work, photocatalysts, including strontium titanate (SrTiO3) and bismuth vanadate (BiVO4), were studied and then further applied in a twin photoreactor to comprise the Z-scheme system. So photocatalytic water splitting achieved high photocatalytic activity, high stability, and high-efficiency separation of gaseous products. For the hydrogen evolution, a series of SrTiO3 were synthesized by the flux molten-salt method and carried out their characterization and photoreaction. The results showed SrTiO3 synthesized using SrCl2·6H2O as molten salt at 1150°C calcination and loaded with cocatalyst, RhxCr2-xO3, by the photodeposition showed the highest hydrogen-evolution rate of 278 μmol h-1 g-1. For oxygen evolution, a series of BiVO4 were synthesized by the hydrothermal method under different situations to evaluate the correlation between photoactivity and the hydrothermal conditions. The results showed that Co-doped BiVO4 synthesized at a pH value of 2 and a period of 10 hours reached the highest oxygen-evolution rate of 493 μmol h-1 g-1. In the twin photoreactor, RhxCr2-xO3/SrTiO3 was used as the hydrogen-evolution photocatalyst, and BiVO4 was used as the oxygen-evolution photocatalyst. Ferric/Ferrous ions served as electron media, and a cation-exchanged Nafion membrane divided the two photocatalysts in the twin photoreactor. As a result, the Z-system of the twin photoreactor can separate hydrogen and oxygen simultaneously during photocatalytic water splitting, thus not only avoiding the recombination of hydrogen and oxygen but also reducing additional separation costs and explosion risk. This research brings in the value of photocatalysts in practical applications.