From QED3 to Self-Dual Multicriticality in the Fradkin-Shenker Model

Abstract

We consider the Fradkin-Shenker Z2 gauge-Higgs lattice model in 2+1 dimensions, i.e. the toric code deformed by an in-plane magnetic field. Its phase diagram contains a multicritical CFT with gapless, mutually non-local electric and magnetic particles, exchanged by a Z2D self-duality symmetry. We introduce a staggered generalization of the model in which these particles carry global U(1)e and U(1)m charges, respectively, and we propose a continuum QFT description in terms of QED3 with Nf = 2 Dirac fermion flavors and a charge-two Higgs field with Yukawa couplings. The conjectured phase diagram harbors a multicritical CFT with (O(2)e × O(2)m)2D symmetry, some of which is emergent in the QFT description. We compute the scaling dimensions of some operators using a large-Nf expansion and find agreement with the emergent selection rules. The staggered model admits a deformation to the original Fradkin-Shenker model, which maps to unit-charge monopole operators in Higgs-Yukawa-QED3 that break the U(1)e × U(1)m symmetry. We show explicitly that this deformation reproduces all features of the Fradkin-Shenker phase diagram. Finally, we propose a multicritical duality between Higgs-Yukawa-QED3 and the easy-plane CP1 model (i.e. two-flavor scalar QED3 with a suitable potential), which describes spin-1/2 anti-ferromagnets on a square lattice. This duality implies a first-order line of N\'eel-VBS transitions ending in a deconfined quantum multicritical point, described by the same O(2)e × O(2)m symmetric CFT that arises in the staggered Fradkin-Shenker model, which separates it from a gapped Z2 spin liquid phase.