Design of Sn-doped cadmium chalcogenide based monolayers for valleytronics properties

TL;DR

This paper designs and analyzes Sn-doped cadmium chalcogenide monolayers, revealing their potential for valleytronics applications through band structure modifications, spin-splitting effects, and stability assessments.

Contribution

It introduces Sn-doped cadmium chalcogenide monolayers with enhanced valleytronic properties and confirms their stability and potential for synthesis.

Findings

Sn doping increases spin-splitting in valleys.

Valley-spin coupling is strong in doped monolayers.

Sn-doped monolayers exhibit significant Berry curvature.

Abstract

Valleytronics, that uses the valley index or valley pseudospin to encode information, has emerged as an interesting field of research in two-dimensional (2D) systems with promising device applications. Spin-orbit coupling (SOC) and inversion symmetry breaking leads to spin-splitting of bands near the energy extrema (valleys). In order to find a new 2D material useful for valleytronics, we have designed hexagonal planar monolayers of cadmium chalcogenides (CdX, X = S, Se, Te) from the (111) surface of bulk CdX zinc blende structure. Band structure study reveals valence band local maxima at symmetry point K and its time reversal conjugate point K$\textquotesingle$. Application of SOC initiates spin-splitting in the valleys that lifts the energy degeneracy and shows strong valley-spin coupling character. We have substituted two Cd atoms in the planar monolayers by Sn atoms which increases the spin-splitting significantly. The structural, dynamic, mechanical and thermal stability of all the monolayers has been confirmed. Values of formation energies indicate that it may be feasible to synthesize the Sn-doped CdSe and CdTe monolayers using bottom-up approach. Zeeman-type spin-splitting is observed in the valley region and Rashba spin-splitting is observed at the $\Gamma$ point for Sn-doped CdSe and CdTe monolayers. Berry curvature values are more in all the Sn-doped monolayers than the pristine monolayers. These newly designed monolayers are thus found to be suitable for valleytronics applications. Sn-doped monolayers show band inversion deep in the valence and conduction bands between Sn~$s$ and $p$ and X~$p$ states but lack topological properties.