E∞1,2-type Lieb-Schultz-Mattis anomalies, deconfined quantum critical points, and non-invertible symmetry breaking

Abstract

We study deconfined quantum critical points (DQCP) associated with Lieb-Schultz-Mattis (LSM) anomalies in one-dimensional spin chains. Our starting point is a structural characterization of the LSM anomaly in the Lyndon-Hochschild-Serre spectral sequence: ωLSM∈ E∞1,2= H1( Ztrans,H2(Gint,U(1)))⊂eq H3(Gintρ Ztrans,U(1)). Physically, this class decorates a translation defect with a projective representation of the internal symmetry Gint. We show that gauging the internal symmetry in the presence of an E∞1,2-type anomaly necessarily produces a non-invertible dual symmetry. This gives a general mechanism for type-II DQCP: in contrast to type-I examples with E∞2,1-type anomalies which are dual to ordinary group-like symmetry breaking, type-II transitions are dual to spontaneous breaking of a non-invertible symmetry. We illustrate the mechanism using a spin-1/2 chain with an anomalous D8 LSM symmetry. We construct a dimer-to-ferromagnet DQCP candidate, provide numerical evidence for a critical theory with central charge c≈ 1, and show, using both category theory and explicit lattice constructions, that gauging the internal symmetry yields the non-invertible Rep(H8) dual symmetry.