Instanton confinement-deconfinement transitions: The stability of pseudogap phases and topological order

TL;DR

This paper investigates the stability of topological and pseudogap phases in quantum many-body systems at finite temperatures, revealing conditions for their existence and proposing experimental signatures of instanton deconfinement transitions.

Contribution

It introduces a generalized renormalization group method to analyze instanton confinement and deconfinement, establishing the stability of topological orders at finite temperatures and classifying instanton suppression universality classes.

Findings

Topological orders can persist at finite temperatures.

Relativistic liquids of topological defects are stable at finite temperatures.

Two universality classes of instanton suppression are identified.

Abstract

We explore the stability of certain many-body quantum states which may exist at zero or finite temperatures, may lack long-range order and even topological order, and still are thermodynamically distinct from uncorrelated disordered phases. We sharply characterize such states by the conservation of topological charge, or equivalently confinement of instantons, using a generalization of the Wilson loop and the correlation length of an emergent gauge field. Our main conclusions are: (i) topological orders can exist at finite temperatures, (ii) relativistic liquids of topological defects can also exist as stable phases at finite temperatures, and (iii) there are two universality classes of instanton suppression. We also relate the instanton dynamics to the problem of the pseudogap state in underdoped cuprates. A universal experimental signature of the instanton deconfinement transition is a change of the quantum noise spectrum, which can perhaps be measured in some situations, for example via a quantum anomaly, or indirectly detected with a specific heat jump. The method of analysis is a functional renormalization group that generalizes the Coulomb gas treatment of Kosterlitz and Thouless to arbitrary interactions and dimensions. In particular, we construct an exact non-perturbative technique for confining interactions between instantons, which introduce irreparable infra-red divergences in the standard perturbative approaches.