Phase and Charge reentrant phase transitions in two capacitively coupled Josephson arrays with ultra-small junction
Abstract
We have studied the phase diagram of two capacitively coupled Josephson junction arrays with charging energy, Ec, and Josephson coupling energy, EJ. Our results are obtained using a path integral Quantum Monte Carlo algorithm. The parameter that quantifies the quantum fluctuations in the i-th array is defined by αi EciEJi. Depending on the value of αi, each independent array may be in the semiclassical or in the quantum regime: We find that thermal fluctuations are important when α 1.5 and the quantum fluctuations dominate when 2.0 α . We have extensively studied the interplay between vortex and charge dominated individual array phases. The two arrays are coupled via the capacitance C inter at each site of the lattices. We find a reentrant transition in (T,α), at low temperatures, when one of the arrays is in the semiclassical limit (i.e. α1=0.5 ) and the quantum array has 2.0 ≤α2 ≤ 2.5, for the values considered for the interlayer capacitance. In addition, when 3.0 ≤ α2 < 4.0, and for all the inter-layer couplings considered above, a novel reentrant phase transition occurs in the charge degrees of freedom, i.e. there is a reentrant insulating-conducting transition at low temperatures. We obtain the corresponding phase diagrams and found some features that resemble those seen in experiments with 2D JJA.
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