Josephson junction detector of non-Gaussian noise

TL;DR

This paper develops a theoretical framework using Josephson junctions to detect non-Gaussian noise in mesoscopic conductors, focusing on higher order cumulants and escape rates, with a novel approach extending Onsager-Machlup theory.

Contribution

It introduces a thermodynamic approach to analyze non-Gaussian noise detection via Josephson junctions, accounting for feedback and weak noise limits.

Findings

Third cumulant effects are measurable through escape rate dependence.

Deviations from Gaussian noise are mainly captured by an effective temperature.

The theory provides asymptotically exact escape rate results for all damping strengths.

Abstract

The measurement of higher order cumulants of the current noise generated by a nonlinear mesoscopic conductor using a Josephson junction as on-chip detector is investigated theoretically. The paper addresses the regime where the noise of the mesoscopic conductor initiates activated escape of the Josephson detector out of the zero-voltage state, which can be observed as a voltage rise. It is shown that the deviations from Johnson-Nyquist noise can mostly be accounted for by an effective temperature which depends on the second noise cumulant of the conductor. The deviations from Gaussian statistics lead to rather weak effects and essentially only the third cumulant can be measured exploiting the dependence of the corrections to the rate of escape from the zero-voltage state on the direction of the bias current. These corrections vanish as the bias current approaches the critical current. The theory is based on a description of irreversible processes and fluctuations in terms of state variables and conjugate forces. This approach, going back to work by Onsager and Machlup, is extended to account for non-Gaussian noise, and it is shown that the thermodynamically conjugate force to the electric charge plays a role similar to the counting field introduced in more recent approaches to describe non-Gaussian noise statistics. The theory allows to obtain asymptotically exact results for the rate of escape in the weak noise limit for all values of the damping strength of the Josephson detector. Also the feedback of the detector on the noise generating conductor is fully taken into account by treating both coupled mesoscopic devices on an equal footing.