Enhancing catalyst activity of two-dimensional C4N2 through doping for the hydrogen evolution reaction

Abstract

This study investigates the structural, electronic, and catalytic properties of pristine and doped C4N2 nanosheets as potential electrocatalysts for the hydrogen evolution reaction. The pristine C36N18 nanosheets exhibit limited HER activity, primarily due to high positive Gibbs free energies (> 2.2 eV). To enhance catalytic performance, doping with B, Si, or P at the nitrogen site was explored. Among these systems, B-doped C36N17 nanosheets exhibit the most promising catalytic activity, with a Gibbs free energy close to zero (≈ -0.2 eV), indicating efficient hydrogen adsorption. Band structure, projected density of states, charge density, and Bader charge analyses reveal significant changes in the electronic environment due to doping. While stacking configurations (AA'A'' and ABC) have minimal effect on catalytic performance, doping -- particularly with B -- substantially alters the electronic structure, optimizing hydrogen adsorption and facilitating efficient HER. These findings suggest that B-doped C36N17 nanosheets could serve as efficient cocatalysts when combined with metallic materials, offering a promising approach to enhance catalytic efficiency in electrocatalytic and photocatalytic applications.

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