Cooper-Pair Tunneling in Small Josephson Junction Arrays under Radio-Frequency Irradiation

TL;DR

This study investigates how radio-frequency microwaves affect Coulomb blockade in small Josephson junction arrays, revealing power and magnetic field-dependent effects with implications for sensitive on-chip detection.

Contribution

It provides a detailed analysis of microwave influence on Coulomb blockade in Josephson arrays, including magnetic field effects and potential for detection applications.

Findings

Coulomb blockade voltage decreases with microwave power.

Frequency-independent scaling of voltage-power plots.

Magnetic field influences microwave power renormalization.

Abstract

The influence of radio frequency microwaves on the Coulomb blockade characteristics in small Josephson junctions was studied using a one-dimensional array of ten small Al tunnel junctions in the frequency range from 1 MHz to 1000 MHz. Coulomb blockade voltage ($V_{\rm th}$) is diminished with increasing microwave power ($V_{\rm ac}$), where the $V_{\rm th}$-$V_{\rm ac}$ plots for varied frequencies fall on a single curve. We observed and theoretically analyzed a magnetic field $dependent$ renormalization of the applied microwave power, in addition to a magnetic-field $independent$ renormalization effect explained using an effective circuit approach of the array. Due to its high sensitivity to microwave power, the array is well-suited for on-chip detection applications in low temperature environments.