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Theoretical evidence of the spin–valley coupling and valley polarization in two-dimensional MoSi<sub>2</sub>X<sub>4</sub> (X = N, P, and As)

Haoqiang Ai, Di Liu, Jiazhong Geng, Shuangpeng Wang, Kin Ho Lo, Hui Pan

2021Physical Chemistry Chemical Physics82 citationsDOI

Abstract

Very recently, the centimeter-scale MoSi2N4 monolayer was synthesized experimentally and exhibited a semiconducting nature with high mobility (Hong et al., Science, 2020, 369, 670-674). Here, we show that MoSi2N4 and its analogues, MoSi2P4 and MoSi2As4, are potential two-dimensional (2D) materials for valleytronics based on first-principles calculations. We demonstrate that the intrinsic inversion symmetry breaking and strong spin-orbital coupling lead to the remarkable spin-valley coupling in the inequivalent valleys at K and K' points, which result in not only the valley-contrasting transport properties, but also the spin and valley coupled optical selection rules. Moreover, the in-plane strain can tune the bandgaps and spin splitting or even induce an indirect-to-direct bandgap transition for promising application in the strain-tunable valleytronics. We find that the valley polarization can be generated by doping magnetic element. Our findings offer theoretical insight into the exotic physical properties of novel MoSi2N4-family materials beyond transition metal dichalcogenides.

Topics & Concepts

Polarization (electrochemistry)Condensed matter physicsCoupling (piping)Spin (aerodynamics)PhysicsMaterials scienceMolecular physicsChemistryPhysical chemistryThermodynamicsMetallurgy2D Materials and ApplicationsGraphene research and applicationsMXene and MAX Phase Materials