Rationally designed transition metal hydroxide nanosheet arrays on graphene for artificial CO2 reduction

The performance of transition metal hydroxides, as cocatalysts for CO 2 photoreduction, is significantly limited by their inherent weaknesses of poor conductivity and stacked structure. Herein, we report the rational assembly of a series of transition metal hydroxides on graphene to act as a cocatalyst ensemble for efficient CO 2 photoreduction. In particular, with the Ru-dye as visible light photosensitizer, hierarchical Ni(OH) 2 nanosheet arrays-graphene (Ni(OH) 2 -GR) composites exhibit superior photoactivity and selectivity, which remarkably surpass other counterparts and most of analogous hybrid photocatalyst system. The origin of such superior performance of Ni(OH) 2 -GR is attributed to its appropriate synergy on the enhanced adsorption of CO 2 , increased active sites for CO 2 reduction and improved charge carriers separation/transfer. This work is anticipated to spur rationally designing efficient earth-abundant transition metal hydroxides-based cocatalysts on graphene and other two-dimension platforms for artificial reduction of CO 2 to solar chemicals and fuels. The development of effective, earth-abundant cocatalysts is critical for photocatalytic CO 2 reduction. Here, authors report the assembly of transition metal hydroxides on graphene to act as cocatalyst ensembles for efficient CO 2 photoreduction.