A promising type-II β-AsP/g-C6N6 van der Waals heterostructure photocatalyst for water splitting: a first-principles study

Photocatalytic water splitting, which can use abundant and clean solar energy, is friendly to the environment and consumes less energy. This work predicts the type-II beta-AsP/g-C6N6 van der Waals (vdW) heterostructure as a promising photocatalyst for water splitting using first-principles calculations. Compared with the g-C6N6 monolayer, the beta-AsP/g-C6N6 heterostructure not only can effectively separate photogenerated electron and hole pairs but also shows considerable light absorption and better photocatalyst performances. The optical absorption coefficient of the beta-AsP/g-C6N6 heterostructure has also extremely increased, more than ten times that of the g-C6N6 monolayer. The beta-AsP/g-C6N6 heterostructure with little compression (-2%) could be conducive to the hydrogen evolution reaction with a Gibbs free energy closer to zero (-0.46 eV) compared to monolayers. The oxygen evolution reaction has a low theoretical overpotential of 0.63 V. These results indicate that it exhibits favorable performances as a photocatalyst. This work predicts the possible application of the beta-AsP/g-C6N6 heterostructure as a photocatalyst and expands the scope of renewable energy devices.