Physical Review Research (Sep 2024)

Physical properties and electronic structure of the two-gap superconductor V_{2}Ga_{5}

  • P.-Y. Cheng,
  • Mohamed Oudah,
  • T.-L. Hung,
  • C.-E. Hsu,
  • C.-C. Chang,
  • J.-Y. Haung,
  • T.-C. Liu,
  • C.-M. Cheng,
  • M.-N. Ou,
  • W.-T. Chen,
  • L. Z. Deng,
  • C.-C. Lee,
  • Y.-Y. Chen,
  • C.-N. Kuo,
  • C.-S. Lue,
  • Janna Machts,
  • Kenji M. Kojima,
  • Alannah M. Hallas,
  • C.-L. Huang

DOI
https://doi.org/10.1103/PhysRevResearch.6.033253
Journal volume & issue
Vol. 6, no. 3
p. 033253

Abstract

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We present a thorough investigation of the physical properties and superconductivity of the binary intermetallic V_{2}Ga_{5}. Electrical resistivity and specific heat measurements show that V_{2}Ga_{5} enters its superconducting state below T_{sc}= 3.5 K, with a critical field of H_{c2,⊥c}(H_{c2,||c})=6.5(4.1) kOe. With H⊥c, the peak effect was observed in resistivity measurements, indicating the ultrahigh quality of the single crystal studied. The resistivity measurements under high pressure reveal that the T_{sc} is suppressed linearly with pressure and reaches absolute zero around 20 GPa. Specific heat and muon spin relaxation measurements indicate that the two-gap s-wave model best describes the superconductivity of V_{2}Ga_{5}. The bands near the Fermi level around the Z and Γ points are observed and analyzed by the angle-resolved photoemission spectroscopy measurements and first-principles band structure calculations. We therefore conclude that V_{2}Ga_{5} is a phonon-mediated two-gap s-wave superconductor.