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Effect of Exchange Interaction and Spin-Orbit Coupling on Spin Splitting in CdSnX (X = S, Se and Te) nanoribbons

We have studied the topological properties of free standing Sn doped cadmium chalcogenide (CdSnX, X = S, Se and Te) nanoribbons of varying widths and three types of edges viz., distorted armchair, normal armchair and normal zigzag edges. The unsatisfied bonds of X and Sn atoms at the edges cause non-zero values of the magnetic moment. This introduces an exchange field leading to inverted band structure. The electronic band structures of distorted armchair edge nanoribbons also exhibit different types of spin splitting property for different X atoms due to the different local orbital angular momentum at specific X atomic site with the inclusion of spin orbit coupling (SOC). The gap opening at the band crossings near the Fermi level after inclusion of SOC are mainly due to SOC of Sn atom and are responsible for the electron and hole pockets making the system topologically exotic. All the distorted edge nanoribbons show metallic behaviour with non-zero magnetic moments. Amongst CdX (X = S, Se and Te) nanoribbons, systems containing S atoms exhibit Weyl-like semi-metallic behavior and not much change with width, that of Se atoms exhibit Zeeman-type spin splitting and significant change with varying width, whereas systems containing Te atoms show signature of Rashba spin splitting along with Zeeman-type spin splitting and moderate change with varying width. The armchair edge nanoribbons show wide gap semiconducting behaviour. Zeeman-type spin splitting is seen in the valence band region for systems containing S atoms and Rashba spin splitting is visible in the conduction band region for systems containing Se and Te atoms. For zigzag edge nanoribbons, no such signature of spin splitting is observed although all the nanoribbons acquire very high magnetic moments.