Spin-orbit quantum impurity in a topological magnet.
Jia-Xin YinNana ShumiyaYuxiao JiangHuibin ZhouGennevieve MacamHano Omar Mohammad SuraSongtian S ZhangZi-Jia ChengZurab GuguchiaYangmu LiQi WangMaksim LitskevichIlya BelopolskiXian P YangTyler A CochranGuoqing ChangQi ZhangZhi-Quan HuangFeng-Chuan ChuangHsin LinHe-Chang LeiBrian M AndersenZiqiang WangShuang JiaM Zahid HasanPublished in: Nature communications (2020)
Quantum states induced by single-atomic impurities are at the frontier of physics and material science. While such states have been reported in high-temperature superconductors and dilute magnetic semiconductors, they are unexplored in topological magnets which can feature spin-orbit tunability. Here we use spin-polarized scanning tunneling microscopy/spectroscopy (STM/S) to study the engineered quantum impurity in a topological magnet Co3Sn2S2. We find that each substituted In impurity introduces a striking localized bound state. Our systematic magnetization-polarized probe reveals that this bound state is spin-down polarized, in lock with a negative orbital magnetization. Moreover, the magnetic bound states of neighboring impurities interact to form quantized orbitals, exhibiting an intriguing spin-orbit splitting, analogous to the splitting of the topological fermion line. Our work collectively demonstrates the strong spin-orbit effect of the single-atomic impurity at the quantum level, suggesting that a nonmagnetic impurity can introduce spin-orbit coupled magnetic resonance in topological magnets.