Negative Poisson's Ratio in 1T-Type Crystalline Two-Dimensional Transition Metal Dichalcogenides
Liping Yu, Qimin Yan, and Adrienn Ruzsinszky

TL;DR
This paper reports the discovery of a new class of 2D materials with intrinsic negative Poisson's ratio, driven by electronic effects, which could enable novel multifunctional applications.
Contribution
First principles calculations reveal a new class of 1T-type monolayer transition-metal dichalcogenides with intrinsic auxetic behavior due to electronic coupling.
Findings
Exhibit negative in-plane Poisson's ratio
Distinct crystal structure from known auxetics
Auxetic behavior driven by electronic effects
Abstract
Materials with a negative Poisson's ratio, also known as auxetic materials, exhibit unusual and counterintuitive mechanical behavior - becoming fatter in cross-section when stretched. Such behavior is mostly attributed to some special reentrant or hinged geometric structures regardless the chemical composition and electronic structure of a material. Here, using first principles calculations, we report a new class of auxetic single-layer two-dimensional (2D) materials, i.e., the 1T-type monolayer crystals of groups 6-7 transition-metal dichalcogenides, MX (M = Mo, W, Tc, Re; X = S, Se, Te). These materials have a crystal structure distinct from all other known auxetic materials. They exhibit an intrinsic in-plane negative Poisson's ratio, which is dominated by the electronic effects. We attribute the occurrence of such auxetic behavior to the strong coupling between the chalcogen p…
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