npj Quantum Materials (Mar 2022)

Spin-triplet superconductivity in Weyl nodal-line semimetals

  • Tian Shang,
  • Sudeep K. Ghosh,
  • Michael Smidman,
  • Dariusz Jakub Gawryluk,
  • Christopher Baines,
  • An Wang,
  • Wu Xie,
  • Ye Chen,
  • Mukkattu O. Ajeesh,
  • Michael Nicklas,
  • Ekaterina Pomjakushina,
  • Marisa Medarde,
  • Ming Shi,
  • James F. Annett,
  • Huiqiu Yuan,
  • Jorge Quintanilla,
  • Toni Shiroka

DOI
https://doi.org/10.1038/s41535-022-00442-w
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 9

Abstract

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Abstract Topological semimetals are three dimensional materials with symmetry-protected massless bulk excitations. As a special case, Weyl nodal-line semimetals are realized in materials having either no inversion or broken time-reversal symmetry and feature bulk nodal lines. The 111-family, including LaNiSi, LaPtSi and LaPtGe materials (all lacking inversion symmetry), belongs to this class. Here, by combining muon-spin rotation and relaxation with thermodynamic measurements, we find that these materials exhibit a fully-gapped superconducting ground state, while spontaneously breaking time-reversal symmetry at the superconducting transition. Since time-reversal symmetry is essential for protecting the normal-state topology, its breaking upon entering the superconducting state should remarkably result in a topological phase transition. By developing a minimal model for the normal-state band structure and assuming a purely spin-triplet pairing, we show that the superconducting properties across this family can be described accurately. Our results demonstrate that the 111 materials reported here provide an ideal test-bed for investigating the rich interplay between the exotic properties of Weyl nodal-line fermions and unconventional superconductivity.