AI Article Synopsis
- Researchers are exploring new 2D magnetic materials with desirable properties like high Curie temperature and carrier mobility, which is crucial for advancements in technology.
- A newly predicted material, Ta2S3 monolayer, features unique single-spin Dirac fermion states and a band structure that promises excellent electrical performance similar to graphene.
- Ta2S3 is stable in ambient conditions, has strong magnetic properties, and could lead to innovative applications in data storage and spintronic devices thanks to its unique characteristics like being a Chern insulator.
Article Abstract
Recent experimental success in the realization of two-dimensional (2D) magnetism has invigorated the search for new 2D magnetic materials with a large magnetocrystalline anisotropy, high Curie temperature, and high carrier mobility. Using first-principles calculations, here we predict a novel class of single-spin Dirac fermion states in a 2D Ta2S3 monolayer, characterized by a band structure with a large gap in one spin channel and a Dirac cone in the other with carrier mobility comparable to that of graphene. Ta2S3 is dynamically and thermodynamically stable under ambient conditions, and possesses a large out-of-plane magnetic anisotropy energy and a high Curie temperature (TC = 445 K) predicted from the spin-wave theory. When the spin and orbital degrees of freedom are allowed to couple, the Ta2S3 monolayer becomes a Chern insulator with a fully spin-polarized half-metallic edge state. An effective four-band tight-binding model is constructed to clarify the origin of a semi-Dirac cone in a spin-up channel and nontrivial band topology, which can be well maintained on a semiconducting substrate. The combination of these unique single-spin Dirac fermion and quantum anomalous Hall states renders the 2D Ta2S3 lattice a promising platform for applications in topologically high fidelity data storage and energy-efficient spintronic devices.
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| http://dx.doi.org/10.1039/c9nr00826h | DOI Listing |
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