# Clearly Discriminate the Continuum Band and Exciton State of the Hybrid   Lead Bromide Perovskite

**Authors:** Jiangjian Shi, Yiming Li, Jionghua Wu, Huijue Wu, Yanhong Luo, Dongmei, Li, Jacek J. Jasieniak, Qingbo Meng

arXiv: 1906.12084 · 2020-08-06

## TL;DR

This study clarifies the electronic structure of hybrid lead bromide perovskites by directly observing free carrier emissions and distinguishing exciton states from the continuum band, resolving longstanding controversies.

## Contribution

It introduces a method to directly discriminate between continuum band and exciton states in hybrid perovskites, advancing understanding of their electronic mechanisms.

## Key findings

- Direct observation of free carrier emissions
- Dual-peak emissions are excitonic in origin
- Excitons have giant binding energies and high phase stability

## Abstract

Electronic states of the hybrid perovskite enable their promising applications as distinctive optoelectronic materials. The understanding of their electronic structures and charge characters remains highly controversial. The electronic mechanism such as reabsorption, Urbach tail and indirect band for interpreting dual-peak emissions is one of the controversial focuses. Herein, we report that through heterojunction enhanced exciton dissociation and global tracing of multiple radiative electronic states across wide temperature regions, we have succeeded in directly observing free carrier emissions from the hybrid lead bromide perovskite and clearly discriminating the direct continuum band and exciton states. The widely-concerned dual-peak emissions are clarified to be excitonic, arising from two types of exciton states of the perovskite. These excitons possess giant binding energies and superior phase stability compared to conventional inorganic semiconductors, providing important implications for exploiting the excitonic mechanism for realizing novel optoelectronic applications.

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Source: https://tomesphere.com/paper/1906.12084