Electron correlations and T-breaking density wave order in a Z2 kagome metal

Abstract

There have been extensive recent developments on kagome metals, such as TmXn (T= Fe, Co and X= Sn, Ge) and AV3Sb5 (A= Cs, K, Rb). An emerging issue is the nature of correlated phases when topologically non-trivial bands cross the Fermi level. Here, we consider an extended Hubbard model on the kagome lattice in the presence of spin-orbit couplings, involving a Kramer's pair of bands that have opposite Chern numbers and are isolated in the band structure. We construct an effective model in a time-reversal (T) symmetric lattice description. We determine the correlated phases of this model and identify a density-wave order in the phase diagram. We show that this order is T-breaking, which originates from the Wannier orbitals lacking a common Wannier center -- a fingerprint of the underlying Z2 topology. Implications of our results for the correlation physics of the kagome metals are discussed.