Stretching ReS2along different crystal directions: Anisotropic tuning of the vibrational and optical responses

Hao Li; Der Yuh Lin; Anna Di Renzo; Sergio Puebla; Riccardo Frisenda; Xuetao Gan; Jorge Quereda; Yong Xie; Abdullah M. Al-Enizi; Ayman Nafady; Andres Castellanos-Gomez

doi:10.1063/5.0081127

Stretching ReS₂along different crystal directions: Anisotropic tuning of the vibrational and optical responses

Hao Li, Der Yuh Lin, Anna Di Renzo, Sergio Puebla, Riccardo Frisenda, Xuetao Gan, Jorge Quereda, Yong Xie, Abdullah M. Al-Enizi, Ayman Nafady, Andres Castellanos-Gomez

School of Microelectronics

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

12 Scopus citations

Abstract

Rhenium disulfide (ReS2) is a semiconducting two-dimensional material with marked in-plane structural anisotropy. This lattice anisotropy is the stem of many quasi-1D properties observed in this material. In this work, we focus on strain engineering of optical and vibrational properties through mechanical deformations of the lattice. In particular, the exciton energy can be shifted by applying uniaxial strain, and the gauge factor is six times more pronounced when the strain is applied along the b-axis than in perpendicular to the b-axis of the ReS2 lattice. Moreover, we also observed how the two most prominent Raman modes can be shifted by uniaxial strain, and the shift strongly depends on the alignment between the uniaxial strain direction and the a- and b-axes of the ReS2 lattice.

Original language	English
Article number	063101
Journal	Applied Physics Letters
Volume	120
Issue number	6
DOIs	https://doi.org/10.1063/5.0081127
State	Published - 7 Feb 2022

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title = "Stretching ReS2along different crystal directions: Anisotropic tuning of the vibrational and optical responses",

abstract = "Rhenium disulfide (ReS2) is a semiconducting two-dimensional material with marked in-plane structural anisotropy. This lattice anisotropy is the stem of many quasi-1D properties observed in this material. In this work, we focus on strain engineering of optical and vibrational properties through mechanical deformations of the lattice. In particular, the exciton energy can be shifted by applying uniaxial strain, and the gauge factor is six times more pronounced when the strain is applied along the b-axis than in perpendicular to the b-axis of the ReS2 lattice. Moreover, we also observed how the two most prominent Raman modes can be shifted by uniaxial strain, and the shift strongly depends on the alignment between the uniaxial strain direction and the a- and b-axes of the ReS2 lattice.",

author = "Hao Li and Lin, {Der Yuh} and {Di Renzo}, Anna and Sergio Puebla and Riccardo Frisenda and Xuetao Gan and Jorge Quereda and Yong Xie and Al-Enizi, {Abdullah M.} and Ayman Nafady and Andres Castellanos-Gomez",

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T1 - Stretching ReS2along different crystal directions

T2 - Anisotropic tuning of the vibrational and optical responses

AU - Li, Hao

AU - Lin, Der Yuh

AU - Di Renzo, Anna

AU - Puebla, Sergio

AU - Frisenda, Riccardo

AU - Gan, Xuetao

AU - Quereda, Jorge

AU - Xie, Yong

AU - Al-Enizi, Abdullah M.

AU - Nafady, Ayman

AU - Castellanos-Gomez, Andres

PY - 2022/2/7

Y1 - 2022/2/7

N2 - Rhenium disulfide (ReS2) is a semiconducting two-dimensional material with marked in-plane structural anisotropy. This lattice anisotropy is the stem of many quasi-1D properties observed in this material. In this work, we focus on strain engineering of optical and vibrational properties through mechanical deformations of the lattice. In particular, the exciton energy can be shifted by applying uniaxial strain, and the gauge factor is six times more pronounced when the strain is applied along the b-axis than in perpendicular to the b-axis of the ReS2 lattice. Moreover, we also observed how the two most prominent Raman modes can be shifted by uniaxial strain, and the shift strongly depends on the alignment between the uniaxial strain direction and the a- and b-axes of the ReS2 lattice.

AB - Rhenium disulfide (ReS2) is a semiconducting two-dimensional material with marked in-plane structural anisotropy. This lattice anisotropy is the stem of many quasi-1D properties observed in this material. In this work, we focus on strain engineering of optical and vibrational properties through mechanical deformations of the lattice. In particular, the exciton energy can be shifted by applying uniaxial strain, and the gauge factor is six times more pronounced when the strain is applied along the b-axis than in perpendicular to the b-axis of the ReS2 lattice. Moreover, we also observed how the two most prominent Raman modes can be shifted by uniaxial strain, and the shift strongly depends on the alignment between the uniaxial strain direction and the a- and b-axes of the ReS2 lattice.

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Stretching ReS₂along different crystal directions: Anisotropic tuning of the vibrational and optical responses

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