Scaling dimension of $4\pi$-flux monopole operator in four-flavor three-dimensional QED using lattice simulation

Author:

Nikhil Karthik, Rajamani Narayanan

Keyword:

High Energy Physics - Lattice, High Energy Physics - Lattice (hep-lat), Strongly Correlated Electrons (cond-mat.str-el), High Energy Physics - Theory (hep-th)

journal:

date:

2024-01-03 00:00:00

Abstract

We numerically address the issue of which monopole operators are relevant under renormalization group flow in three-dimensional parity-invariant noncompact QED with $4$ flavors of massless two-component Dirac fermion. Using lattice simulation and finite-size scaling analysis of the free energy to introduce monopole-antimonopole pairs in $N=4$ and $N=12$ flavor noncompact QED$_3$, we estimate the infrared scaling dimensions of monopole operators that introduce $2\pi$ and $4\pi$ fluxes around them. We first show that the estimates for the monopole scaling dimensions are consistent with the large-$N$ expectations for $N=12$ QED$_3$. Applying the same procedure in $N=4$ QED$_3$, we estimate the scaling dimension of $4\pi$ flux monopole operator to be $3.7(3)$, which allows the possibility of the operator being irrelevant. This finding offers support to the scenario in which higher-flux monopoles are irrelevant deformations to the Dirac spin liquid phase that could be realized on certain non-bipartite lattices by forbidding $2\pi$-flux monopoles.

PDF: Scaling dimension of $4\pi$-flux monopole operator in four-flavor three-dimensional QED using lattice simulation.pdf