Full solar spectrum photocatalytic oxygen evolution by carbon-coated TiO2 hierarchical nanotubes.

Graphical abstract Highlights • Hierarchical TiO 2 nanotube with uniform carbon coatings is synthesized successfully. • The TiO 2 /C hierarchical nanotube exhibits the best photocatalytic activity under full solar spectrum light irradiation. • The incorporation of visible/NIR light active carbon coating with UV light responsive TiO 2 promote solar utilization. • The hierarchical nanotube can generate multiple reflections of incident light to promote an efficient light harvesting. • The generated carbon coatings on the surface of TiO 2 facilitate electron-hole separation. Abstract Smart architectures of TiO 2 are attracting increasing attention due to their outstanding properties in a broad range of fields. Herein, hierarchical TiO 2 nanotube with uniform carbon coatings is synthesized as the full solar spectrum photocatalytic materials for O 2 evolution by a facile solvothermal method. This unique structure consists of an interstitial hollow spaces and a functional nanotube shell assembled from two-dimensional (2D) nanosheets. By adjusting the types of solvents and reaction time, the morphologies of TiO 2 /C composites can be tuned to nanoparticles, nanorods, or hierarchical nanotubes. Among these morphologies, the TiO 2 / C hierarchical nanotube exhibits the best photocatalytic activity and favorable stability toward oxygen evolution from water oxidation under full solar spectrum light irradiation. The reason is attributed to the desirable incorporation of visible/near-infrared (NIR) light active carbon coating with UV light responsive TiO 2 for promoted solar energy utilization. Besides, the solvothermal step leads to hierarchical nanotube structures which can generate multiple reflections of incident light so as to promote an efficient light harvesting due to an enhanced specific surface area (244.4 m2 g−1) and light scattering ability. Moreover, the generated carbon coatings on the surface of TiO 2 facilitate electron-hole separation. [ABSTRACT FROM AUTHOR]