Abstract

Abstract Recent years have seen a surge in the use of low-dimensional transition metal dichacolgenides, such as MoS 2 , as catalysts for the electrochemical hydrogen evolution reaction. In particular, sulfur vacancies in MoS 2 can activate the inert basal plane, but that requires an unrealistically high defect concentration (~9%) to achieve optimal activity. In this work, we demonstrate by first-principles calculations that assembling van der Waals heterostructures can enhance the catalytic activity of MoS 2 with low concentrations of sulfur vacancies. We integrate MoS 2 with various two-dimensional nanostructures, including graphene, h -BN, phosphorene, transition metal dichacolgenides, MXenes, and their derivatives, aiming to fine-tune the free energy of atomic hydrogen adsorption. Remarkably, an optimal free energy can be achieved for a low sulfur vacancy concentration of ~2.5% in the MoS 2 /MXene-OH heterostructure, as well as high porosity and tunability. These results demonstrate the potential of combining two-dimensional van der Waals assembly with defect engineering for efficient hydrogen production.