Density Functional Theory Study of Two-Dimensional Post-Transition Metal Chalcogenides and Halides for Interfacial Charge Transport in Perovskite Solar Cells

This computational study focuses on charge transport using two-dimensional (2D) materials as interfacial materials in perovskite solar cells (PSCs). Layered structures of post-transition metal chalcogenides (InS, InSe, PbI2) and Tin and Lead monoxides (SnO and PbO) are studied using density functional theory (DFT). An assessment using hybrid exchange-correlation energies was conducted for variation in the electronic properties with an increase in the number of 2D layers of these materials. Their band edge positions are then compared with that of MAPbI3perovskite (as an archetypal PSC material) and assessed for use as charge-transport material. Further analysis of charge density distribution, planar potential variation, and Bader charge analysis was conducted for the monolayer/perovskite interfaces (PbO/MAPbI3and InSe/MAPbI3). Monolayered lead monoxide (PbO) and double-layered tin monoxide (SnO) were useful for transporting holes, while hexagonal phases of InS and InSe are suitable for electron transport in PSCs.