Self-Doping Surface Oxygen Vacancy-Induced Lattice Strains for Enhancing Visible Light-Driven Photocatalytic H Evolution over Black TiO.

The synergistic effect of surface oxygen vacancy with induced lattice strains on visible light-driven photocatalytic H evolution over black TiO was investigated. Experimental measurements and theoretical calculations on the lattice parameters of black TiO show that surface oxygen vacancies induce internal lattice strain during two-step aluminothermic reduction, which regulates the band structure and optimizes the photoinduced charge behavior of black TiO. The hydrogen evolution rate of black TiO with strain modification shows a 12-fold increase to 1.882 mmol/g· h (equal to 4.705 μmol/cm·h) under visible light illumination. The metastable state caused by the surface oxygen vacancies leads to the formation of a high-energy surface, which enhances visible light absorption and improves the photoinduced charge separation efficiency. Furthermore, the internal lattice strain provides the driving force and channel for the directional movement of photoinduced electrons from the bulk to the high-energy surface for photocatalytic H evolution. This strategy provides a new method for designing a high-performance photocatalyst for H production.