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:10.1038/s41535-022-00442-w

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^*

^*Corresponding author for this work

School of Physics and Electronic Science

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

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.

Original language	English
Article number	35
Journal	npj Quantum Materials
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s41535-022-00442-w
State	Published - Dec 2022

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Shang, T., Ghosh, S. K., Smidman, M., Gawryluk, D. J., Baines, C., Wang, A., Xie, W., Chen, Y., Ajeesh, M. O., Nicklas, M., Pomjakushina, E., Medarde, M., Shi, M., Annett, J. F., Yuan, H., Quintanilla, J., & Shiroka, T. (2022). Spin-triplet superconductivity in Weyl nodal-line semimetals. npj Quantum Materials, 7(1), Article 35. https://doi.org/10.1038/s41535-022-00442-w

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title = "Spin-triplet superconductivity in Weyl nodal-line semimetals",

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.",

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

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year = "2022",

month = dec,

doi = "10.1038/s41535-022-00442-w",

language = "英语",

volume = "7",

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T1 - Spin-triplet superconductivity in Weyl nodal-line semimetals

AU - Shang, Tian

AU - Ghosh, Sudeep K.

AU - Smidman, Michael

AU - Gawryluk, Dariusz Jakub

AU - Baines, Christopher

AU - Wang, An

AU - Xie, Wu

AU - Chen, Ye

AU - Ajeesh, Mukkattu O.

AU - Nicklas, Michael

AU - Pomjakushina, Ekaterina

AU - Medarde, Marisa

AU - Shi, Ming

AU - Annett, James F.

AU - Yuan, Huiqiu

AU - Quintanilla, Jorge

AU - Shiroka, Toni

PY - 2022/12

Y1 - 2022/12

N2 - 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.

AB - 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.

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DO - 10.1038/s41535-022-00442-w

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VL - 7

JO - npj Quantum Materials

JF - npj Quantum Materials

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ER -

Spin-triplet superconductivity in Weyl nodal-line semimetals

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