Non-Fermi liquid from confinement in doped Mott insulators

TL;DR

This paper introduces a gauge theory-based phenomenological model for doped Mott insulators, showing that confinement of fractionalized excitations leads to non-Fermi liquid behavior and offers insights into unconventional superconductivity.

Contribution

It proposes a novel confinement mechanism using the Polyakov loop in an SU(2) gauge theory, explaining non-Fermi liquid behavior without quantum criticality in doped Mott insulators.

Findings

Confined electrons exhibit non-Fermi liquid physics.

Resistivity matches experimental data.

Higgs phase is suppressed by confinement.

Abstract

A phenomenological description for confinement of fractionalized excitations is proposed in the gauge theory approach for doped Mott insulators. Introducing the Polyakov-loop parameter into an SU(2) gauge theory for the t-J model, we show that electron excitations emerge below the so-called coherence temperature, resulting from confinement of spinons and holons via the formation of the Polyakov loop. Remarkably, such confined electrons turn out to exhibit non-Fermi liquid physics without quantum criticality, yielding the electric resistivity in quantitative agreement with experimental data. The Higgs phase is not allowed due to confinement, suggesting a possible novel mechanism of superconductivity in the strong coupling approach.