Intrinsic dissipation in superconducting junctions probed by qubit spectroscopy

TL;DR

This paper proposes using qubit spectroscopy to investigate frequency-dependent intrinsic dissipation in highly transparent Josephson junctions, focusing on contributions from Andreev bound states and their effect on qubit relaxation.

Contribution

It introduces a method to probe dissipation sources in Josephson junctions via qubit energy relaxation measurements, highlighting the role of Andreev bound states.

Findings

Spectral density of dissipation can be tuned by bias current or magnetic flux.

Qubit relaxation times reveal contributions from Andreev bound states.

Method enables unambiguous identification of dissipation sources.

Abstract

We propose to study frequency dependent intrinsic dissipation in a highly transparent Josephson junction by means of qubit spectroscopy. The spectral density of the effective dissipative bath may contain significant contributions from Andreev bound states coupled to fluctuations of the Josephson phase. Varying either the bias current applied to the junction or magnetic flux through a superconducting ring in the rf-SQUID setup, one can tune the level splitting value close to the bottom of the Josephson potential well. Monitoring the qubit energy relaxation time one can probe the spectral density of the effective dissipative bath and unambiguously identify the contribution emerging from Andreev levels.