Failure of the Quench Action Formalism for Mott Insulator Initial States

Abstract

The quench action formalism relies on the assumption that the overlap between a generic initial state |Ψ0 and an eigenstate of an integrable model - defined through the rapidities |k1,...kN - can be written as: equation k1,...kNΨ0 =(-SΨ0(ρ(k))),eq:Exponential equation where ρ(k) is the quasiparticle density of the state |k1,...kN and SΨ0 is some smooth function of ρ(k) that depends on Ψ0. In particular the quench action formalism assumes the overlap depends smoothly on the quasiparticle density ρ(k). In this work, by explicit counter example, we show that this is not the case. We consider the quench between a Mott insulator and a Lieb Liniger gas. We show that the overlap between the ground state of the Mott insulator and arbitrary eigenstates of the Lieb Liniger gas has a highly singular behavior and no expression like Eq. (1) applies. We do so within the Tonks Girardeau limit of the Lieb Liniger gas and to leading order in the 1/c expansion for the overlap (with c being the coupling constant of the Lieb Liniger gas). In the Appendix we show similar results for overlaps in the XXZ model with crystal states.