Li Chenyao, Li Minghang, Li Yefeng, He Tingli, Liu Ying, Zhang Xiaoming, Dai Xuefang, Liu Guodong
State Key Laboratory of Reliability and Intelligence of Electrical Equipment, Hebei University of Technology, Tianjin 300130, People's Republic of China.
School of Materials Science and Engineering, Hebei University of Technology, Tianjin 300130, People's Republic of China.
J Phys Condens Matter. 2023 Apr 6;35(26). doi: 10.1088/1361-648X/acc8b2.
Two-dimensional (2D) half-metal and topological states have been the current research focus in condensed matter physics. Herein, we report a novel 2D material named EuOBr monolayer, which can simultaneously show 2D half-metal and topological fermions. This material shows a metallic state in the spin-up channel but a large insulating gap of 4.38 eV in the spin-down channel. In the conducting spin channel, the EuOBr monolayer shows the coexistence of Weyl points and nodal-lines near the Fermi level. These nodal-lines are classified by type-I, hybrid, closed, and open nodal-lines. The symmetry analysis suggests these nodal-lines are protected by the mirror symmetry, which cannot be broken even spin-orbit coupling is included because the ground magnetization direction in the material is out-of-plane [001]. The topological fermions in the EuOBr monolayer are fully spin-polarized, which can be meaningful for future applications in topological spintronic nano-devices.
二维(2D)半金属和拓扑态一直是凝聚态物理当前的研究热点。在此,我们报道了一种名为溴氧化铕单层的新型二维材料,它能同时展现二维半金属和拓扑费米子特性。这种材料在自旋向上通道呈现金属态,但在自旋向下通道有4.38电子伏特的大绝缘能隙。在导电自旋通道中,溴氧化铕单层在费米能级附近展现出外尔点和节线的共存。这些节线可分为I型、混合型、闭合型和开放型节线。对称性分析表明这些节线受镜面对称性保护,即便包含自旋轨道耦合也不会被破坏,因为材料中的基态磁化方向垂直于平面[001]。溴氧化铕单层中的拓扑费米子完全自旋极化,这对拓扑自旋电子纳米器件的未来应用可能具有重要意义。