Generalized symmetries in singularity-free nonlinear σ models and their disordered phases
Abstract
We study the nonlinear σ-model in (d+1)-dimensional spacetime with connected target space K and show that, at energy scales below singular field configurations (such as vortices), it has an emergent non-invertible higher symmetry. The symmetry defects of the emergent symmetry are described by the d-representations of a discrete d-group G(d) (i.e. the emergent symmetry is the dual of the invertible d-group G(d) symmetry). The d-group G(d) is determined such that its classifying space BG(d) is given by the d-th Postnikov stage of K. In (2+1)D and for finite G(2), this symmetry is always holo-equivalent to an invertible 0-form (ordinary) symmetry with potential 't Hooft anomaly. The singularity-free disordered phase of the nonlinear σ-model spontaneously breaks this symmetry, and when G(d) is finite, it is described by the deconfined phase of G(d) higher gauge theory. We consider examples of such disordered phases. We focus on a singularity-free S2 nonlinear σ-model in (3+1)D and show that it has an emergent non-invertible higher symmetry. As a result, its disordered phase is described by axion electrodynamics and has two gapless modes corresponding to a photon and a massless axion. Notably, this non-perturbative result is different from the results obtained using the SN and CPN-1 nonlinear σ-models in the large-N limit.
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