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Active Asymmetric Electron-Transfer Effect on the Enhanced Piezoelectricity in MoTO (T = S, Se, or Te) Monolayers and Bilayers

Yunqin Li, Xinyu Wang, Xinyu Wang, Shiyu Zhu, Dai-Song Tang, Qiwen He, Xiao-Chun Wang, Xiao-Chun Wang

2022The Journal of Physical Chemistry Letters44 citationsDOI

Abstract

Development of piezoelectric materials is limited partly due to the incompleteness of internal mechanism and the lack of vertical piezoelectricity. Herein, we theoretically identify the stable MoTO (T = S, Se, or Te) monolayers and bilayers. When two elements are given but another element can be changed, the larger the electronegativity difference ratio Rratio is, the stronger the piezoelectricity will be. Vertical piezoelectric coefficient d33 of the MoTeO bilayer reaches 38.907 pm/V, which is 12 times larger than that of the bulk GaN. The “active asymmetric electron-transfer” strategy mainly contributes to the spontaneous remarkable piezoelectricity of MoTO. Importantly, we proposed the new method for calculating the piezoelectric coefficients of two-dimensional (2D) materials, which corresponds to the fact that 2D materials have a certain thickness. This study not only provides novel extraordinary candidates for energy conversion and touch-sensor nanodevices but also promotes a deeper understanding of piezoelectricity of 2D materials.

Topics & Concepts

PiezoelectricityMonolayerElectronegativityBilayerCondensed matter physicsMaterials sciencePiezoelectric coefficientNanogeneratorElectronNanotechnologyOptoelectronicsChemistryPhysicsComposite materialMembraneBiochemistryOrganic chemistryQuantum mechanics2D Materials and ApplicationsPerovskite Materials and ApplicationsAdvanced Thermoelectric Materials and Devices