Abstract
Mechanical properties of two-dimensional (2D) transition-metal dichalcogenides (TMDCs) are of vital importance in any practical applications to flexible devices and nano-electromechanical systems. Thus, the mechanical properties of monolayer TMDCs, a stoichiometric formula MX2 in which M = Mo, W and X = S, Se, Te, are investigated by using density functional theory. More importantly, based on the different atomic arrangement, all three chemical isomers, such as 1T, 1T′, and 1H phases, are compared in detail. We found that their 2D Young’s moduli and Poisson’s ratios display a strong dependence not only on the atomic species but also on the atomic arrangements. For the same structural phase, monolayer TMDCs with the W (S) atom are found to be much stiffer in each chalcogenide (metal) group. Due to the threefold rotation symmetry of the hexagonal lattice, 1T- and 1H-TMDC monolayers belong to the isotropic structures, while the strong anisotropic Young’s moduli and Poisson’s ratios are observed in the 1T′ phase, i.e., 2D Young’s moduli along the armchair direction are nearly 50% larger than those along the zigzag direction for tellurides. Interestingly, 1T-TMDC monolayers show negative Poisson’s ratios. Furthermore, their in-plane 1H/1T′ heterostructures could be constructed, and the corresponding mechanical properties are explored. We found that the influence of the 1H/1T′ interface on the mechanical behavior is detrimental, which reduces the in-plane stiffness normal to the 1H/1T′ interface as compared with 1H and 1T′ structures. However, in comparison with the 1T′ phase, a remarkable strength of these novel heterostructures is along the 1H/1T′ interface direction. In brief, the present first-principles results constitute a useful picture for the mechanical properties of 2D TMDCs and their in-plane heterostructures.
Highlights
Transition-metal dichalcogenides (TMDCs) are a family of two-dimensional (2D) materials with a chemical composition of MX2, where M is a transition metal and X = S, Se, Te
In this study, we present a detailed density functional theory calculations to investigate the mechanical properties of two-dimensional transition-metal dichalcogenides (TMDCs) associated with 1T, 1T′, and 1H phases
Our results clearly indicate that all the TMDCs considered in this study are less stiff than graphene, which makes them attractive substitutes or alternatives in applications requiring flexible semiconductor materials
Summary
Young’s moduli of multilayered 1H-WSe2 were measured, and they were 596 ± 23, 690 ± 25, and 1411 ± 61 N/m for 5-, 6-, and 12-layer thick membranes, respectively.6 These experimental results could be well understood within a nonlinear elastic constitutive equation.. Similar to their electronic behaviors, 1T′-MX2 exhibit rather anisotropic elastic properties, which are less studied.15,24 In this manuscript, we present a detailed investigation of 2D Young’s moduli and Poisson’s ratios of monolayer 1T- and 1T′MX2 (M = Mo, W and X = S, Se, Te) and compare them with those of the 1H phase in detail by conducting extensive density functional simulations. Heterostructures made from different structural phases in seamlessly stitched forms will further show novel mechanical properties.15 In this context, several TMDCs-based heterostructures have been experimentally realized by using selectively decorated molecules or electrostatic doping..
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