Lieb-Schultz-Mattis constraints from stratified anomalies of modulated symmetries

Abstract

We introduce stratified symmetry operators and stratified anomalies in quantum lattice systems as generalizations of onsite symmetry operators and onsite projective representations. A stratified symmetry operator is a symmetry operator that factorizes into mutually independent subsystem symmetry operators; its stratified anomaly is defined as the collection of anomalies associated with these subsystem operators. We develop a cellular chain complex formalism for stratified anomalies of internal symmetries and show that, in the presence of crystalline symmetries, they give rise to Lieb-Schultz-Mattis (LSM) constraints. This includes LSM anomalies and SPT-LSM theorems. We apply this framework to modulated G symmetries, which are symmetries whose total symmetry group is Gtot = G Gs, with Gs the crystalline symmetry group. Notably, a nonzero stratified anomaly within a fundamental domain of Gs (e.g., a unit cell) does not always imply an LSM anomaly for modulated symmetries. Instead, the existence of an LSM anomaly also depends on how Gs acts on G. When Gs is the lattice translation group, we find an explicit criterion for when a stratified anomaly causes an LSM anomaly, and classify LSM anomalies using homology groups of Gs-invariant cellular chains. We illustrate this through examples of exponential and dipole symmetries with stratified anomalies, both in (1+1)D and (2+1)D, and construct a stabilizer code model of a modulated SPT subject to an SPT-LSM theorem.