Observation of Massive Dirac Fermions in Ferromagnetic Kagome metal Fe<sub>3</sub>Sn<sub>2</sub>

ORAL

Abstract

Recent theoretical developments suggest that the combination of unusual magnetism, spin-orbit coupling, and geometric frustration in Kagome metal possibly lead to a wide range of novel topological physics, such as fractional quantum Hall effect and intrinsic anomalous Hall effect. In these phenomena, a major role is played by the topologically nontrivial flat bands and massive Dirac cones, both of which are predicted to exist from the unique geometrical hopping pathways of Kagome lattice. Despite these predictions, the experimental band structure of Kagome compounds has long remained unreported. In this talk, we report the experimental band structure of bilayer Kagome compound Fe3Sn2, measured by high-resolution angle-resolved photoemission spectroscopy. We clearly observe a pair of quasi-2D Dirac cones near the Fermi level, with a 30 meV spin-orbit gap that serves as a singular source of Berry curvature. Combined with ferromagnetism in the Kagome plane, this fermiology supports the emergence of intrinsic anomalous Hall conductivity, unambiguously observed by transport measurement over a wide temperature range (0.6 K ~ 400 K). Thus, our experiments establish the first direct link between the electronic structure and emergent topological transport in a correlated Kagome metal.

Presenters

  • Min Gu Kang

    • Massachusetts Inst of Tech-MIT

Authors

  • Min Gu Kang

    • Massachusetts Inst of Tech-MIT

  • Linda Ye

    • Massachusetts Inst of Tech-MIT
    • Massachusetts Institute of Technology
    • Department of Physics, Massachusetts Institute of Technology

  • Junwei Liu

    • Massachusetts Inst of Tech-MIT
    • Physics, Hong Kong University of Science and Technology
    • Physics, MIT

  • Felix Cube

    • Applied physics, Harvard univeristy

  • Christina Wicker

    • Massachusetts Inst of Tech-MIT
    • Massachusetts Institute of Technology

  • Takehito Suzuki

    • Department of Physics, Massachusetts Institute of Technology
    • Massachusetts Inst of Tech-MIT
    • Massachusetts Institute of Technology

  • Chris Jozwiak

    • Advanced light source
    • Lawrence Berkeley Natl Lab
    • Lawrence Berkeley National Laboratory
    • Lawrence Berkeley National Lab
    • Advanced Light Source, Lawrence Berkeley National Laboratory

  • Aaron Bostwick

    • Advanced light source
    • Lawrence Berkeley Natl Lab
    • Lawrence Berkeley National Laboratory
    • Lawrence Berkeley National Lab
    • Advanced Light Source, Lawrence Berkeley National Laboratory

  • Eli Rotenberg

    • Advanced light source
    • Lawrence Berkeley Natl Lab
    • Lawrence Berkeley National Laboratory
    • Lawrence Berkeley National Lab
    • Advanced Light Source, Lawrence Berkeley National Laboratory

  • David Bell

    • Applied physics, Harvard univeristy
    • Harvard Center for Nanoscale Systems
    • Engineering and Applied Sciences, Harvard University

  • Liang Fu

    • Department of Physics, Massachusetts Institute of Technology
    • Massachusetts Inst of Tech-MIT
    • Physics, Massachusetts Inst of Tech-MIT
    • Physics, Massachusetts Institute of Technology
    • Physics, Massachusetts Inst of Technology
    • Physics, MIT
    • Massachusetts Institute of Technology
    • MIT

  • Joseph Checkelsky

    • Department of Physics, Massachusetts Institute of Technology
    • Massachusetts Inst of Tech-MIT
    • Physics, Massachusetts Institute of Technology
    • Massachusetts Institute of Technology
    • Physics, Massachusetts Inst of Tech-MIT

  • Riccardo Comin

    • Massachusetts Inst of Tech-MIT
    • Department of Physics, Massachusetts Institute of Technology
    • Physics, Massachusetts Inst of Tech-MIT