Symmetry Breaking from Monopole Condensation in QED3

Abstract

QED in three dimensions with an SU(2)f doublet i of massless, charge-1 Dirac fermions (and no Chern-Simons term) has a U(2) = (SU(2)f × U(1)m)/Z2 symmetry that acts on gauge-invariant local operators, including monopole operators charged under U(1)m. We establish that there are only two possible IR scenarios: either the theory flows to a CFT with U(2) symmetry (a scenario strongly constrained by conformal bootstrap bounds); or it spontaneously breaks U(2) U(1) via the condensation of a monopole operator of smallest U(1)m charge, which is a U(2) doublet. This leads to three Nambu-Goldstone bosons described by a sigma model into a squashed three-sphere S3 with U(2) isometry. We further show that the conventional SU(2)f-triplet order parameter i σ \, also gets a vev, exactly aligned with the monopole vev, such that the triplet parametrizes the CP1 base of the S3 Hopf bundle, with the monopoles providing the S1 fibers. We also recall why this scenario is compatible with the Vafa-Witten theorem. We obtain these results by analyzing the phase diagram as a function of the fermion triplet mass m: we show that for all m ≠ 0 there is a Coulomb phase with only a weakly-coupled photon at low energies, arising from a monopole vev that is aligned with m via the Hopf map. We then argue that taking m 0 leads to the symmetry-breaking scenario above. Throughout, we give a detailed account of anomaly matching, which leads to a θ=π term in the S3 sigma model. In one presentation, it can be understood as a Hopf term in a suitably gauged version of the CP1 sigma model.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…