Physical Review X (Jun 2021)

Coexistence of Surface Superconducting and Three-Dimensional Topological Dirac States in Semimetal KZnBi

  • Junseong Song,
  • Sunghun Kim,
  • Youngkuk Kim,
  • Huixia Fu,
  • Jahyun Koo,
  • Zhen Wang,
  • Gyubin Lee,
  • Jouhahn Lee,
  • Sang Ho Oh,
  • Joonho Bang,
  • Taku Matsushita,
  • Nobuo Wada,
  • Hiroki Ikegami,
  • Jonathan D. Denlinger,
  • Young Hee Lee,
  • Binghai Yan,
  • Yeongkwan Kim,
  • Sung Wng Kim

DOI
https://doi.org/10.1103/PhysRevX.11.021065
Journal volume & issue
Vol. 11, no. 2
p. 021065

Abstract

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We report the discovery of a new three-dimensional (3D) topological Dirac semimetal (TDS) material KZnBi, coexisting with a naturally formed superconducting state on the surface under ambient pressure. Using photoemission spectroscopy together with first-principles calculations, a 3D Dirac state with linear band dispersion is identified. The characteristic features of massless Dirac fermions are also confirmed by magnetotransport measurements, exhibiting an extremely small cyclotron mass of m^{*}=0.012 m_{0} and a high Fermi velocity of v_{F}=1.04×10^{6} m/s. Interestingly, superconductivity occurs below 0.85 K on the (001) surface, while the bulk remains nonsuperconducting. The captured linear temperature dependence of the upper critical field suggests the possible non-s-wave character of this surface superconductivity. Our discovery serves a distinctive platform to study the interplay between 3D TDS and the superconductivity.