Long-range Coulomb interaction in nodal-ring semimetals

TL;DR

This paper investigates the effects of long-range Coulomb interactions in nodal-ring semimetals, revealing a nontrivial fixed point and discussing unique experimental signatures of quasiparticles.

Contribution

It introduces a detailed analysis of Coulomb interactions in nodal-ring semimetals, identifying a nontrivial fixed point and exploring its implications for physical properties.

Findings

Identification of a nontrivial interacting fixed point

Screened Coulomb interaction is an irrelevant perturbation

Predicted experimental signatures include anisotropic conductivity and phonon dispersion

Abstract

Recently there have been several proposals of materials predicted to be nodal-ring semimetals, where zero energy excitations are characterized by a nodal ring in the momentum space. This class of materials falls between the Dirac-like semimetals and the more conventional Fermi-surface systems. As a step towards understanding this unconventional system, we explore the effects of the long-range Coulomb interaction. Due to the vanishing density of states at the Fermi level, Coulomb interaction is only partially screened and remains long-ranged. Through renormalization group and large-$N_f$ computations, we have identified a nontrivial interacting fixed point. The screened Coulomb interaction at the interacting fixed point is an irrelevant perturbation, allowing controlled perturbative evaluations of physical properties of quasiparticles. We discuss unique experimental consequences of such quasiparticles: acoustic wave propagation, anisotropic dc conductivity, and renormalized phonon dispersion as well as energy dependence of quasiparticle lifetime.