Strain-engineering on GeSe: Raman spectroscopy study

Jin Jin Wang; Yi Feng Zhao; Jun Ding Zheng; Xiao Ting Wang; Xing Deng; Zhao Guan; Ru Ru Ma; Ni Zhong; Fang Yu Yue; Zhong Ming Wei; Ping Hua Xiang; Chun Gang Duan

doi:10.1039/d1cp03721h

Strain-engineering on GeSe: Raman spectroscopy study

Jin Jin Wang
, Yi Feng Zhao
, Jun Ding Zheng
, Xiao Ting Wang
, Xing Deng
, Zhao Guan
, Ru Ru Ma
, Ni Zhong^*
, Fang Yu Yue
, Zhong Ming Wei
, Ping Hua Xiang
, Chun Gang Duan

^*Corresponding author for this work

School of Physics and Electronic Science

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

Abstract

Among the IV-VI compounds, GeSe has wide applications in nanoelectronics due to its unique photoelectric properties and adjustable band gap. Even though modulation of its physical characteristics, including the band gap, by an external field will be useful for designing novel devices, experimental work is still rare. Here, we report a detailed anisotropic Raman response of GeSe flakes under uniaxial tension strain. Based on theoretical analysis, the anisotropy of the phonon response is attributed to a change in anisotropic bond length and bond angle under in-plane uniaxial strain. An enhancement in anisotropy and band gap is found due to strain along the ZZ or AC directions. This study shows that strain-engineering is an effective method for controlling the GeSe lattice, and paves the way for modulating the anisotropic electric and optical properties of GeSe.

Original language	English
Pages (from-to)	26997-27004
Number of pages	8
Journal	Physical Chemistry Chemical Physics
Volume	23
Issue number	47
DOIs	https://doi.org/10.1039/d1cp03721h
State	Published - 21 Dec 2021

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10.1039/d1cp03721h

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title = "Strain-engineering on GeSe: Raman spectroscopy study",

abstract = "Among the IV-VI compounds, GeSe has wide applications in nanoelectronics due to its unique photoelectric properties and adjustable band gap. Even though modulation of its physical characteristics, including the band gap, by an external field will be useful for designing novel devices, experimental work is still rare. Here, we report a detailed anisotropic Raman response of GeSe flakes under uniaxial tension strain. Based on theoretical analysis, the anisotropy of the phonon response is attributed to a change in anisotropic bond length and bond angle under in-plane uniaxial strain. An enhancement in anisotropy and band gap is found due to strain along the ZZ or AC directions. This study shows that strain-engineering is an effective method for controlling the GeSe lattice, and paves the way for modulating the anisotropic electric and optical properties of GeSe.",

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doi = "10.1039/d1cp03721h",

language = "英语",

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TY - JOUR

T1 - Strain-engineering on GeSe

T2 - Raman spectroscopy study

AU - Wang, Jin Jin

AU - Zhao, Yi Feng

AU - Zheng, Jun Ding

AU - Wang, Xiao Ting

AU - Deng, Xing

AU - Guan, Zhao

AU - Ma, Ru Ru

AU - Zhong, Ni

AU - Yue, Fang Yu

AU - Wei, Zhong Ming

AU - Xiang, Ping Hua

AU - Duan, Chun Gang

PY - 2021/12/21

Y1 - 2021/12/21

N2 - Among the IV-VI compounds, GeSe has wide applications in nanoelectronics due to its unique photoelectric properties and adjustable band gap. Even though modulation of its physical characteristics, including the band gap, by an external field will be useful for designing novel devices, experimental work is still rare. Here, we report a detailed anisotropic Raman response of GeSe flakes under uniaxial tension strain. Based on theoretical analysis, the anisotropy of the phonon response is attributed to a change in anisotropic bond length and bond angle under in-plane uniaxial strain. An enhancement in anisotropy and band gap is found due to strain along the ZZ or AC directions. This study shows that strain-engineering is an effective method for controlling the GeSe lattice, and paves the way for modulating the anisotropic electric and optical properties of GeSe.

AB - Among the IV-VI compounds, GeSe has wide applications in nanoelectronics due to its unique photoelectric properties and adjustable band gap. Even though modulation of its physical characteristics, including the band gap, by an external field will be useful for designing novel devices, experimental work is still rare. Here, we report a detailed anisotropic Raman response of GeSe flakes under uniaxial tension strain. Based on theoretical analysis, the anisotropy of the phonon response is attributed to a change in anisotropic bond length and bond angle under in-plane uniaxial strain. An enhancement in anisotropy and band gap is found due to strain along the ZZ or AC directions. This study shows that strain-engineering is an effective method for controlling the GeSe lattice, and paves the way for modulating the anisotropic electric and optical properties of GeSe.

UR - https://www.scopus.com/pages/publications/85121245864

U2 - 10.1039/d1cp03721h

DO - 10.1039/d1cp03721h

M3 - 文章

AN - SCOPUS:85121245864

SN - 1463-9076

VL - 23

SP - 26997

EP - 27004

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 47

ER -

Strain-engineering on GeSe: Raman spectroscopy study

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