Mo_6S_6 nanowires: structural, mechanical and electronic properties

TL;DR

This study uses ab-initio calculations to explore the structural, mechanical, and electronic properties of Mo_6S_6 nanowires, revealing their potential as quasi-one-dimensional conductors with strong uniaxial characteristics.

Contribution

It provides detailed theoretical insights into Mo_6S_6 nanowires' properties, highlighting their mechanical resilience and electronic behavior, which were previously not well characterized.

Findings

Mo_6S_6 nanowires are weakly coupled one-dimensional chains.

They exhibit high elastic moduli and resilience along the chain axis.

The electronic structure indicates good quasi-one-dimensional conductivity.

Abstract

The properties of Mo_6S_6 nanowires were investigated with ab-initio calculations based on the density-functional theory. The molecules build weakly coupled one-dimensional chains, like Mo_6Se_6 and Mo_6S_(9-x)I_x, and the crystals are strongly uniaxial in their mechanical and electronic properties. The calculated moduli of elasticity and resilience along the chain axis are c_(11) = 320 GPa and E_R = 0.53 GPa, respectively. The electronic band structure and optical conductivity indicate that the Mo_6S_6 crystals are good quasi-one-dimensional conductors. The frequency-dependent complex dielectric tensor epsilon, calculated in the random-phase approximation, shows a strong Drude peak in epsilon_parallel, i.e., for the electric field polarised parallel to the chain axis, and several peaks related to interband transitions. The electron energy loss spectrum is weakly anisotropic and has a strong peak at the plasma frequency (hbar omega_p) is approx 20 eV. The stability analysis shows that Mo_6S_6 is metastable against the formation of the layered MoS_2.