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Article Abstract
MoTe_{2}, a promising material for flexible electronics and straintronics, exhibits rapid strain-induced conductivity changes. However, the underlying mechanisms remain poorly understood. Here, through deep-learning molecular dynamics and density-functional theory calculations, we identify a reversible phase transition between the semiconductive T_{b}^{'} phase and the semimetallic T^{*} phase as the key mechanism driving this phenomenon. This transition, which is highly sensitive to the direction of applied strain, provides valuable insights for optimizing MoTe_{2}-based high-frequency nanoelectronic devices and reducing fabrication-related failures.
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| http://dx.doi.org/10.1103/4zbf-rkbl | DOI Listing |
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