Pressure-Induced Indirect-Direct Bandgap Transition of CsPbBr Single Crystal and Its Effect on Photoluminescence Quantum Yield

Overview

Journal Adv Sci (Weinh)

Specialty Biomedical Engineering

Date 2022 Aug 10

PMID 35948500

Authors

Junbo Gong

Hongxia Zhong

Chan Gao

Jiali Peng

Xinxing Liu

Qianqian Lin

Guojia Fang

Shengjun Yuan

Zengming Zhang

Xudong Xiao

Affiliations

Soon will be listed here.

Abstract

Despite extensive study, the bandgap characteristics of lead halide perovskites are not well understood. Usually, these materials are considered as direct bandgap semiconductors, while their photoluminescence quantum yield (PLQY) is very low in the solid state or single crystal (SC) state. Some researchers have noted a weak indirect bandgap below the direct bandgap transition in these perovskites. Herein, application of pressure to a CsPbBr SC and first-principles calculations reveal that the nature of the bandgap becomes more direct at a relatively low pressure due to decreased dynamic Rashba splitting. This effect results in a dramatic PLQY improvement, improved more than 90 times, which overturns the traditional concept that the PLQY of lead halide perovskite SC cannot exceed 10%. Application of higher pressure transformed the CsPbBr SC into a pure indirect bandgap phase, which can be maintained at near-ambient pressure. It is thus proved that lead halide perovskites can induce a phase transition between direct and indirect bandgaps. In addition, distinct piezochromism is observed for a perovskite SC for the first time. This work provides a novel framework to understand the optoelectronic properties of these important materials.

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