Tuning the Parity Mixing of Singlet-Septet Pairing in a Half-Heusler Superconductor

In superconductors, electrons with spin \({s=1/2}\) form Cooper pairs whose spin structure is usually singlet (\({S=0}\)) or triplet (\({S=1}\)). When the electronic structure near the Fermi level is characterized by fermions with angular momentum \({j=3/2}\) due to strong spin-orbit interactions, n...

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Bibliographic Details
Published in:arXiv.org 2021-12
Main Authors: Ishihara, K, Takenaka, T, Miao, Y, Mizukami, Y, Hashimoto, K, Yamashita, M, Konczykowski, M, Masuki, R, Hirayama, M, Nomoto, T, Arita, R, Pavlosiuk, O, Wisniewski, P, Kaczorowski, D, Shibauchi, T
Format: Article
Language:English
Subjects:
Admixtures
Angular momentum
Carrier density
Cooper pairs
Electron irradiation
Electron spin
Electronic structure
Electrons
Fermions
Parity
Penetration depth
Spin structure
Spin-orbit interactions
Superconductivity
Superconductors
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Summary:In superconductors, electrons with spin \({s=1/2}\) form Cooper pairs whose spin structure is usually singlet (\({S=0}\)) or triplet (\({S=1}\)). When the electronic structure near the Fermi level is characterized by fermions with angular momentum \({j=3/2}\) due to strong spin-orbit interactions, novel pairing states such as even-parity quintet (\({J=2}\)) and odd-parity septet (\({J=3}\)) states become allowed. Prime candidates for such exotic states are half-Heusler superconductors, which exhibit unconventional superconducting properties, but their pairing nature remains unsettled. Here we show that the superconductivity in the noncentrosymmetric half-Heusler LuPdBi can be consistently described by the admixture of isotropic even-parity singlet and anisotropic odd-parity septet pairing, whose ratio can be tuned by electron irradiation. From magnetotransport and penetration depth measurements, we find that carrier concentrations and impurity scattering both increase with irradiation, resulting in a nonmonotonic change of the superconducting gap structure. Our findings shed new light on our fundamental understanding of unconventional superconducting states in topological materials.
ISSN:2331-8422
DOI:10.48550/arxiv.2110.01819