Curvature-dependent Flexible Light Emission from Layered Gallium Selenide Crystals

Overview

Journal RSC Adv

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2022 May 11

PMID 35541498

Authors

Ching-An Chuang

Min-Han Lin

Bo-Xian Yeh

Ching-Hwa Ho

Affiliations

Soon will be listed here.

Abstract

Flexible optoelectronics devices play an important role for technological applications of 2D materials because of their bendable, flexible and extended two-dimensional surfaces. In this work, light emission properties of layered gallium selenide (GaSe) crystals with different curvatures have been investigated using bending photoluminescence (BPL) experiments in the curvature range between = 0.00 m (flat condition) and = 30.28 m. A bendable and rotated sample holder was designed to control the curvature (strain) of the layered sample under upward bending uniformly. The curvature-dependent BPL results clearly show that both bandgaps and BPL intensities of the GaSe are curvature dependent with respect to the bending-radius change. The main emission peak (bandgap) is 2.005 eV for flat GaSe, and is 1.986 eV for the bending GaSe with a curvature of 30.28 m (the maximum bending conditions in this experiment). An obvious redshift ( energy reduction) for the GaSe BPL peak was detected owing to the c-plane lattice expansion by upward bending. The intensities of the corresponding BPL peaks also show an increase with increasing curvature. The correlations between BPL peak intensity, shiny area and bond-angle widening of the bent GaSe under laser excitation have been discussed. The lattice constant emission energies of the bending GaSe was also analyzed. An estimated lattice constant bandgap relation was present for further application of the layered GaSe in bendable flexible light-emission devices.

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