Pseudogaps: A third peak in the fermion spectral function

TL;DR

This paper introduces an exactly solvable model of a pseudogap featuring multiple fermion spectral peaks, revealing how dynamic coupling affects quasiparticle properties and spectral broadening.

Contribution

It presents a novel exactly solvable model demonstrating the impact of a classical frequency source on fermion spectral functions and quasiparticle broadening.

Findings

Infinite poles at multiples of omega_0 in the spectral function

Residue at zero frequency vanishes linearly with omega_0 in adiabatic limit

Multiple poles merge into a continuum, indicating inhomogeneous broadening

Abstract

I present an exactly solvable model of a pseudogap with two zero-energy fermion modes coupled to each other by a classical source of frequency omega_0 and strength |Delta|. A suitably defined fermion propagator has an infinite number of poles at frequencies that are multiple integers of omega_0. In the adiabatic limit, omega_0 << |\Delta|, the situation is qualitatively different from the static case omega_0=0: the residue of the pole at omega=0 (a remnant of the bare fermion) vanishes linearly with omega_0, a result that could not be anticipated by perturbation theory; the multiple poles of the propagator coalesce into a continuum instead of forming two single poles at +-|Delta|, which should be interpreted as inhomogeneous broadening of the Bogoliubov quasiparticles.