Hydrogen-Bond Network Promotes Water Splitting on the TiO 2 Surface.
Xiaochuan MaYongliang ShiJianyi LiuXintong LiXuefeng CuiShijing TanJin ZhaoBing WangPublished in: Journal of the American Chemical Society (2022)
Breaking the strong covalent O-H bond of an isolated H 2 O molecule is difficult, but it can be largely facilitated when the H 2 O molecule is connected with others through hydrogen-bonding. How a hydrogen-bond network forms and performs becomes crucial for water splitting in natural photosynthesis and artificial photocatalysis and is awaiting a microscopic and spectroscopic understanding at the molecular level. At the prototypical photocatalytic H 2 O/anatase-TiO 2 (001)-(1×4) interface, we report the hydrogen-bond network can promote the coupled proton and hole transfer for water splitting. The formation of a hydrogen-bond network is controlled by precisely tuning the coverage of water to above one monolayer. Under ultraviolet (UV) light irradiation, the hydrogen-bond network opens a cascaded channel for the transfer of a photoexcited hole, concomitant with the release of the proton to form surface hydroxyl groups. The yielded hydroxyl groups provide excess electrons to the TiO 2 surface, causing the reduction of Ti 4+ to Ti 3+ and leading to the emergence of gap states, as monitored by in situ UV/X-ray photoelectron spectroscopy. The density functional theory calculation reveals that the water splitting becomes an exothermic process through hole oxidation with the assistance of the hydrogen-bond network. In addition to the widely concerned exotic activity from photocatalysts, our study demonstrates the internal hydrogen-bond network, which is ubiquitous at practical aqueous/catalyst interfaces, is also indispensable for water splitting.