L\'evy noise effects on Josephson junctions

TL;DR

This paper reviews how Le9vy noise influences Josephson junction dynamics, exploring metastable state lifetimes, voltage responses, and switching current distributions to characterize non-Gaussian noise effects.

Contribution

It introduces methods to analyze Le9vy noise effects on Josephson junctions, including new models for noise characterization via switching current distributions.

Findings

Le9vy noise causes nonmonotonic switching times.

Voltage measurements can infer Le9vy stability index.

Distribution of switching currents reveals noise parameters.

Abstract

We review three different approaches to investigate the non-equilibrium stochastic dynamics of a Josephson junction affected by L\'evy-distributed current fluctuations. First, we study the lifetime in the metastable superconducting state of current-biased short and long junctions, in the presence of Gaussian and L\'evy noise sources. We highlight the noise-induced nonmonotonic behavior of the mean switching time as a function of noise intensity and driving frequency, that is the noise enhanced stability and the stochastic resonant activation, respectively. Then, we characterize the L\'evy noise source through the average voltage drop across a current-biased junction. The voltage measurement versus the noise intensity allows to infer the value of the stability index that characterizes L\'evy-distributed fluctuations. The numerical calculation of the average voltage drop across the junction well agrees with the analytical estimate of the average velocity for L\'evy-driven escape processes from a metastable state. Finally, we look at the distribution of switching currents out of the zero-voltage state, when a L\'evy noise signal is added to a linearly ramped bias current. The analysis of the cumulative distribution function of the switching currents gives information on both the L\'evy stability index and the intensity of fluctuations. We present also a theoretical model to catch the features of the L\'evy signal from a measured distribution of switching currents. The phenomena discussed in this work can pave the way for an effective and reliable Josephson-based scheme to characterize L\'evy components eventually embedded in an unknown noisy signal.