Suneetha N, Ananthram K S, Nirmalya Ballav and Kartick Tarafder*,
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引用次数: 0
摘要
首次预测了碘化钇(YI)独特的电子结构,揭示了在同一相内结合自旋极化Dirac和Weyl节点的非平凡拓扑性质。该研究确定了两个自旋通道中存在的节点。Berry曲率图的源汇特征和表面能带结构中费米弧的存在进一步证实了Weyl节点的存在。发现电子和空穴包在Weyl点相连,将YI归类为ii型磁性Weyl半金属。在自旋-轨道耦合(SOC)下,8对Weyl点表现出鲁棒性,而自旋极化的Dirac锥处形成了一个小带隙。该系统还证明了狄拉克费米子的高费米速度,估计约为3.4 × 105 m/s,并且具有高达933 s /cm的巨大各向异性本征异常霍尔电导率。
Coexistence of Spin-Polarized Dirac and Weyl Nodes in 2D Electride Ferromagnet Yttrium Iodide
The unique electronic structure of yttrium iodide (YI) has been predicted for the first time, revealing nontrivial topological properties that combine spin-polarized Dirac and Weyl nodes within the same phase. The study identified nodal points present in both spin channels. The existence of Weyl nodes is further confirmed by the source and sink features in the Berry curvature plot and the presence of Fermi arcs in the surface band structure. The electron and hole packets are found to be connected at the Weyl point, classifying YI as a type-II magnetic Weyl semimetal. Under spin–orbit coupling (SOC), eight pairs of Weyl points exhibit robust behavior, while a small band gap forms at the spin-polarized Dirac cone. The system also demonstrates a high Fermi velocity, estimated at about 3.4 × 105 m/s, for Dirac Fermions and a giant anisotropic intrinsic anomalous Hall conductivity of up to 933 S/cm.
期刊介绍:
The Journal of Physical Chemistry A/B/C is devoted to reporting new and original experimental and theoretical basic research of interest to physical chemists, biophysical chemists, and chemical physicists.
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