Evidence for coherent quantum phase-slips across a Josephson junction array
Abstract
Superconducting order in a sufficiently narrow and infinitely long wire is destroyed at zero temperature by quantum fluctuations, which induce slips of the phase of the order parameter. However, in a finite-length wire coherent quantum phase-slips would manifest themselves simply as shifts of energy levels in the excitations spectrum of an electrical circuit incorporating this wire. The higher the phase-slips probability amplitude, the larger are the shifts. Phase-slips occurring at different locations along the wire interfere with each other. Due to the Aharonov-Casher effect, the resulting full amplitude of a phase-slip depends on the offset charges surrounding the wire. Slow temporal fluctuations of the offset charges make the phase-slips amplitudes random functions of time, and therefore turn energy levels shifts into linewidths. We experimentally observed this effect on a long Josephson junction array acting as a "slippery" wire. The slip-induced linewidths, despite being only of order 100 kHz, were resolved from the flux-dependent dephasing of the fluxonium qubit.
Cite
@article{arxiv.1012.1928,
title = {Evidence for coherent quantum phase-slips across a Josephson junction array},
author = {Vladimir E. Manucharyan and Nicholas A. Masluk and Archana Kamal and Jens Koch and Leonid I. Glazman and Michel H. Devoret},
journal= {arXiv preprint arXiv:1012.1928},
year = {2012}
}
Comments
15 pages