Superconductivity out of a non-Fermi liquid. Free energy analysis

Abstract

In this paper, we present in-depth analysis of the condensation energy Ec for a superconductor in a situation when superconductivity emerges out of a non-Fermi liquid due to pairing mediated by a massless boson. This is the case for electronic-mediated pairing near a quantum-critical point in a metal, for pairing in SYK-type models, and for phonon-mediated pairing in the properly defined limit, when the dressed Debye frequency vanishes. We consider a subset of these quantum-critical models, in which the pairing in a channel with a proper spatial symmetry is described by an effective 0+1 dimensional model with the effective dynamical interaction V(m) = gγ/|m|γ, where γ is model-specific (the γ-model). In previous papers, we argued that the pairing in the γ model is qualitatively different from that in a Fermi liquid, and the gap equation at T=0 has an infinite number of topologically distinct solutions, n (ωm), where an integer n, running between 0 and infinity, is the number of zeros of n (ωm) on the positive Matsubara axis. This gives rise to the set of extrema of Ec at Ec,n, of which Ec,0 is the global minimum. The spectrum Ec,n is discrete for a generic γ <2, but becomes continuous at γ = 2-0. Here, we discuss in more detail the profile of the condensation energy near each Ec,n and the transformation from a discrete to a continuous spectrum at γ 2. We also discuss the free energy and the specific heat of the γ-model in the normal state.