English

Odd-frequency superfluidity from a particle-number-conserving perspective

Superconductivity 2024-08-15 v2 Quantum Gases

Abstract

We investigate odd-in-time - or odd-frequency - pairing of fermions in equilibrium systems within the particle-number-conserving framework of Penrose, Onsager and Yang, where superfluid order is defined by macroscopic eigenvalues of reduced density matrices. We show that odd-frequency pair correlations are synonymous with even fermion-exchange symmetry in a time-dependent correlation function that generalises the two-body reduced density matrix. Macroscopic even-under-fermion-exchange pairing is found to emerge from conventional Penrose-Onsager-Yang condensation in two-body or higher-order reduced density matrices through the symmetry-mixing properties of the Hamiltonian. We identify and characterise a transformer matrix responsible for producing macroscopic even fermion-exchange correlations that coexist with a conventional Cooper-pair condensate, while a generator matrix is shown to be responsible for creating macroscopic even fermion-exchange correlations from hidden orders such as a multi-particle condensate. The transformer scenario is illustrated using the spin-balanced s-wave superfluid with Zeeman splitting as an example. The generator scenario is demonstrated by the composite-boson condensate arising for itinerant electrons coupled to magnetic excitations. Structural analysis of the transformer and generator matrices is shown to provide general conditions for odd-frequency pairing order to arise in a given system. Our formalism facilitates a fully general derivation of the Meissner effect for odd-frequency superconductors that holds also beyond the regime of validity for mean-field theory.

Keywords

Cite

@article{arxiv.2403.06325,
  title  = {Odd-frequency superfluidity from a particle-number-conserving perspective},
  author = {K. Thompson and U. Zülicke and J. Schmalian and M. Governale and J. Brand},
  journal= {arXiv preprint arXiv:2403.06325},
  year   = {2024}
}

Comments

23 pages, 2 figures, RevTex4.2

R2 v1 2026-06-28T15:15:10.037Z