Performance parameters of infra-red and visible-active MXene photocatalysts for water splitting

Water splitting reactions through photocatalysis are an efficient and sustainable technique for the generation of green energy. Ability to simultaneously generate hydrogen and oxygen, along with efficiency of utilizing charge carriers, conversion of solar energy to hydrogen, fast migration, and low recombination rates of carriers are the parameters that decide a photocatalyst's suitability in water splitting. In the literature, comprehensive calculation and analysis of all these performance parameters for a potential photocatalyst are rare. In this work, we have performed first-principles-based computations to find new efficient photocatalysts from the family of Janus MXenes and assessed their performance parameters using strain engineering. Out of 14 studied materials, we find 5 materials: Sc2COS, Zr2COS, Hf2COS, and ZrHfCO2 under zero or finite tensile strain and Hf2COSe under 6% tensile strain meeting the requirements of simultaneous reactions to split water. The computations of various efficiency-related parameters demonstrate that Zr2COS, Hf2COS, and Hf2COSe have excellent efficiencies, significantly better than those of the well-known photocatalysts. The origin of such performances lies in their electronic and optical properties, which are analysed systematically. Water splitting reactions through photocatalysis are an efficient and sustainable technique for the generation of green energy.