Anisotropic spin-split states with canted persistent spin textures in two-dimensional Janus $1T^{'}$ $MXX'$ ($M$ = Mo, W; $X\neq X'$= S, Se, Te) controlled by surface alloying
Autor: | Absor, Moh. Adhib Ulil, Arifin, Muhammad, Santoso, Iman, Harsojo |
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Rok vydání: | 2024 |
Předmět: | |
Druh dokumentu: | Working Paper |
Popis: | Two-dimensional tungsten-based transition metal dichalcogenides (TMDCs), $MX_{2}$ ($M$: W, Mo; $X$: S, Se, Te) monolayers (MLs) with a $1T'$ structure, serve as significant-gap quantum spin Hall insulators. However, due to the centrosymmetric nature of these crystals, spin degeneracy persists throughout their electronic band structures, limiting their potential for spintronic applications. By modifying the chalcogen ($X$) atoms in the TMDCs ML surface to create a highly stable Janus $MXX'$ MLs structure, we demonstrate through density-functional theory calculations that substantial spin splitting of the electronic states can be achieved. Using the Janus $1T'$ WSTe ML as an example, we observe strongly anisotropic spin-splitting bands exhibiting canted persistent spin textures (PST) near the Fermi level, which differ significantly from those in commonly studied PST materials. We show that this intricate spin splitting and spin textures arise from the strong in-plane $p-d$ orbital coupling between the chalcogen atoms (Te and Se) and tungsten (W) atoms, driven by the reduced symmetry of the crystal's point group. The observed anisotropic spin splitting, along with canted PST, are further explained using a $\vec{k}\cdot\vec{p}$ model derived from symmetry analysis. Importantly, the spin-split states are highly sensitive to surface imperfections induced by the surface alloying effect, such as variations in the concentration of different chalcogen atoms on the ML surface. This highlights the potential of Janus $1T'$ $MXX'$ MLs as promising platforms for future spintronic devices. Comment: 5 Figures |
Databáze: | arXiv |
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