Structure-related bandgap of hybrid lead halide perovskites and close-packed APbX3 family of phases

TL;DR

This study systematically predicts and analyzes all possible hexagonal polytypes of hybrid lead halide APbI3 perovskites, revealing how their structure influences bandgap and potentially impacts solar cell efficiency.

Contribution

The paper introduces a comprehensive group theory-based prediction of hexagonal polytypes and their band structures, filling a gap in understanding their configurational space.

Findings

Identified all possible hexagonal polytypes of APbI3 using group theory.

Analyzed the relationship between polytype structure and bandgap via DFT calculations.

Found non-linear dependence of bandgap on layer ratios, affecting charge transport.

Abstract

Metal halide perovskites APbX3 (A+ = FA+ (formamidinium), MA+ (methylammonium) or Cs+, X- = I-, Br-) are considered as prominent innovative components in nowadays perovskite solar cells. Crystallization of these materials is often complicated by the formation of various phases with the same stoichiometry but structural types deviating from perovskites such as well-known the hexagonal delta FAPbI3 polytype. Such phases are rarely placed in the focus of device engineering due to their unattractive optoelectronic properties while they are, indeed, highly important because they influence on the optoelectronic properties and efficiency of final devices. However, the total number of such phases has not been yet discovered and the complete configurational space of the polytypes and their band structures have not been studied systematically. In this work, we predicted and described all possible hexagonal polytypes of hybrid lead halides with the APbI3 composition using the group theory approach, also we analyzed theoretically the relationship between the configuration of close-packed layers in polytypes and their band gap using DFT calculations. Two main factors affecting the bandgap were found including the ratio of cubic (c) and hexagonal (h) close-packed layers and the thickness of blocks of cubic layers in the structures. We also show that the dependence of the band gap on the ratio of cubic (c) and hexagonal (h) layers in these structures are non-linear. We believe that the presence of such polytypes in the perovskite matrix might be a reason for a decrease in the charge carrier mobility and therefore it would be an obstacle for efficient charge transport causing negative consequences for the efficiency of solar cell devices.