Many-body Aharonov-Bohm caging in a lattice of rings

Abstract

We study a system of a few ultracold bosons loaded into the states with orbital angular momentum l=1 of a one-dimensional staggered lattice of rings. Local eigenstates with winding numbers +l and -l form a Creutz ladder with a real dimension and a synthetic one. States with opposite winding numbers in adjacent rings are coupled through complex tunnelings, which can be tuned by modifying the central angle φ of the lattice. We analyze both the single-particle case and the few boson bound-state subspaces for the regime of strong interactions using perturbation theory, showing how the geometry of the system can be engineered to produce an effective π-flux through the plaquettes. We find non-trivial topological band structures and many-body Aharonov-Bohm caging in the N-particle subspaces even in the presence of a dispersive single-particle spectrum. Additionally, we study the family of models where the angle φ is introduced at an arbitrary lattice periodicity . For >2, the π-flux becomes non-uniform, which enlarges the spatial extent of the Aharonov-Bohm caging as the number of flat bands in the spectrum increases. All the analytical results are benchmarked through exact diagonalization.