The quantum transverse-field Ising chain in circuit QED: effects of disorder on the nonequilibrium dynamics
We study several dynamical properties of a recently proposed implementation
of the quantum transverse-field Ising chain in the framework of circuit QED.
Particular emphasis is placed on the effects of disorder on the nonequilibrium
behavior of the system. We show that small amounts of fabrication-induced
disorder in the system parameters do not jeopardize the observation of
previously-predicted phenomena. Based on a numerical extraction of the mean
free path of the system, we also provide a simple quantitative estimate for
certain disorder effects on the nonequilibrium dynamics of the circuit QED
quantum simulator. We discuss the transition from weak to strong disorder,
characterized by the onset of Anderson localization of the system’s wave
functions, and the qualitatively different dynamics it leads to.