Weyl Nodal Line-Surface Half-metal in CaFeO3
Abstract
Manipulating the spin degrees of freedom of electrons affords an excellent platform for exploring novel quantum states in condensed-matter physics and material science. Based on first-principles calculations and analysis of crystal symmetries, we propose a fully spin-polarized composite semimetal state, which is combined with the one-dimensional nodal lines and two-dimensional nodal surfaces, in the half-metal material CaFeO3. In the nodal line-surface states, the Baguenaudier-like nodal lines feature six rings linked together, which are protected by the three independent symmetry operations:PT, My, and Mz. Near the Fermi level, the spin-polarized nodal surface states are guaranteed by the joint operation TS2i in the ki(i=x,y,z)=π plane. Furthermore, high-quality CaFeO3 harbors ultra-clean energy dispersion, which is rather robust against strong triaxial compressional strain and correlation effect. The realization of the Weyl nodal line-surface half-metal presents great potential for spintronics applications with high speed and low power consumption.
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