Quantum dynamics, particle delocalization and instability of Mott states: the effect of fermion–boson conversion on Mott states

Abstract

We study the quantum dynamics of superfluids of bosons hybridized with Cooper pairs near Feshbach resonances and the influence of fermion–boson conversion on Mott states. We derive a set of equations of motion which describe novel low energy dynamics in superfluids and obtain a new distinct branch of gapped collective modes in superfluids which involve anti-symmetric phase oscillations in fermionic and bosonic channels. We also find that Mott states in general are unstable with respect to fermion–boson conversion; particles become delocalized and the off-diagonal long-range order of superfluids can be developed when a finite conversion is present. We further point out a possible hidden order in Mott states. It is shown that the quantum dynamics of Fermi–Bose states can be characterized by either an effective coupled U(1) ⊗ U(1) quantum rotor Hamiltonian in a large-N limit or a coupled XXZ ⊗ XXZ spin Hamiltonian in a single-orbit limit.