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Effects of rare-earth magnetism on the superconducting upper critical field in infinite-layer nickelates.

Bai Yang WangTiffany C WangYu-Te HsuMotoki OsadaKyuho LeeChunjing JiaCaitlin DuffyDanfeng LiJennifer FowlieMalcolm R BeasleyThomas Peter DevereauxIan R FisherNigel E HusseyHarold Y Hwang
Published in: Science advances (2023)
The search for superconductivity in infinite-layer nickelates was motivated by analogy to the cuprates, and this perspective has framed much of the initial consideration of this material. However, a growing number of studies have highlighted the involvement of rare-earth orbitals; in that context, the consequences of varying the rare-earth element in the superconducting nickelates have been much debated. Here, we show notable differences in the magnitude and anisotropy of the superconducting upper critical field across the La-, Pr-, and Nd-nickelates. These distinctions originate from the 4 f electron characteristics of the rare-earth ions in the lattice: They are absent for La 3+ , nonmagnetic for the Pr 3+ singlet ground state, and magnetic for the Nd 3+ Kramer's doublet. The unique polar and azimuthal angle-dependent magnetoresistance found in the Nd-nickelates can be understood to arise from the magnetic contribution of the Nd 3+ 4 f moments. Such robust and tunable superconductivity suggests potential in future high-field applications.
Keyphrases
  • molecularly imprinted
  • high resolution
  • quantum dots
  • density functional theory
  • ionic liquid
  • mass spectrometry
  • molecular dynamics
  • case control