The self-actuating InAs nanowire-based nanoelectromechanical Josephson junction

TL;DR

This paper introduces a self-actuating InAs nanowire-based Josephson junction that uses the a.c. Josephson effect to detect and actuate vibrational modes of a nanoelectromechanical resonator via straightforward d.c. measurements.

Contribution

It demonstrates a novel self-actuating nanowire Josephson junction device that integrates nanoelectromechanical resonator functionalities with superconducting Josephson effects.

Findings

Vibrational modes can be actuated and detected through d.c. transport.

The device operates as a self-actuating nanoelectromechanical system.

The approach simplifies the detection of nanomechanical vibrations.

Abstract

Half a century ago Brian Josephson made a series of striking predictions related to a tunnelling barrier sandwiched between two superconductors. One particular prediction, later became known as the a.c.-Josephson effect, said that under a finite d.c. bias the tunnelling current contains an a.c. supercurrent component, oscillating at microwave frequency. This prediction was experimentally verified through observation of the junction current-voltage characteristics modified by the interaction with the electromagnetic radiation, and direct detection of the microwave radiation emitted from the junction itself. It had also been established that the behaviour of the d.c. current-voltage characteristic is determined by the high-frequency dynamics of the Josephson junction, and can be used to study various systems such as atoms in the electron-spin resonance, optical phonons in high-Tc superconductors, and vibrating Nb molecules. Here we present an InAs nanowire Josephson junction device, where a vibrating nanowire weak link plays the role of a nanoelectromechanical resonator. The flow of the a.c.- Josephson current through the junction enabled actuation and detection of vibrational modes of the resonator by means of simple d.c. transport measurements.