Phase and Charge reentrant phase transitions in two capacitively coupled Josephson arrays with ultra-small junction

TL;DR

This study explores the complex phase transitions in two capacitively coupled Josephson junction arrays, revealing reentrant transitions driven by quantum and thermal fluctuations, with phase diagrams resembling experimental observations.

Contribution

It presents the first detailed analysis of reentrant phase transitions in coupled Josephson arrays considering quantum and thermal effects using Quantum Monte Carlo simulations.

Findings

Reentrant superconductor-insulator transitions at low temperatures.

Quantum fluctuations dominate for $ extstyle 2.0 extless \alpha extless 2.5$.

Phase diagrams resemble experimental 2D Josephson junction arrays.

Abstract

We have studied the phase diagram of two capacitively coupled Josephson junction arrays with charging energy, $E_c$, and Josephson coupling energy, $E_J$. 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 $\alpha_i\equiv \frac{E_{{c}_i}}{E_{J_i}}$. Depending on the value of $\alpha_i$, each independent array may be in the semiclassical or in the quantum regime: We find that thermal fluctuations are important when $\alpha \lesssim 1.5 $ and the quantum fluctuations dominate when $2.0 \lesssim \alpha $. We have extensively studied the interplay between vortex and charge dominated individual array phases. The two arrays are coupled via the capacitance $C_{{\rm inter}}$ at each site of the lattices. We find a {\it reentrant transition} in $\Upsilon(T,\alpha)$, at low temperatures, when one of the arrays is in the semiclassical limit (i.e. $\alpha_{1}=0.5 $) and the quantum array has $2.0 \leq\alpha_{2} \leq 2.5$, for the values considered for the interlayer capacitance. In addition, when $3.0 \leq \alpha_{2} < 4.0$, and for all the inter-layer couplings considered above, a {\it 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.