Theory of coherent phase modes in insulating Josephson junction arrays

Abstract

Recent microwave reflection measurements of Josephson junction ladders have suggested the presence of nearly coherent collective charge oscillations deep in the insulating phase. Here we develop a qualitative understanding of such coherent charge modes by studying the local dynamical conductivity of the insulating phase of a finite length sine-Gordon model. By considering parameters near the non-interacting Fermion limit where the charge operator dominantly couples to soliton-antisoliton pairs of the sine-Gordon model, we find that the local dynamical resistance shows an array of sharp peaks in frequency representing coherent phase oscillations on top of an incoherent background. The strength of the coherent peaks relative to the incoherent background increases as a powerlaw in frequency as well as exponentially as the Luttinger parameter approaches a critical value. The dynamical conductivity also clearly shows the insulating gap. We then compare the results in the high frequency limit to a perturbative estimate of phase-slip-induced decay of plasmons in the Josephson junction ladder.