Charge-Noise Insensitive Chiral Photonic Interface for Waveguide Circuit QED
Abstract
A chiral photonic interface is a quantum system that has different probabilities for emitting photons to the left and right. An on-chip compatible chiral interface is attractive for both fundamental studies of light-matter interactions and applications to quantum information processing. We propose such a chiral interface based on superconducting circuits, which has wide bandwidth, rich tunability, and high tolerance to fabrication variations. The proposed interface consists of a core that uses Cooper-pair boxes (CPBs) to break time-reversal symmetry, and two superconducting transmons that connect the core to a waveguide in the manner reminiscent of a ``giant atom.'' The transmons form a state decoupled from the core, akin to dark states of atomic physics, rendering the whole interface insensitive to the CPB charge noise. The proposed interface can be extended to realize a broadband fully passive on-chip circulator for microwave photons.
Cite
@article{arxiv.2106.15744,
title = {Charge-Noise Insensitive Chiral Photonic Interface for Waveguide Circuit QED},
author = {Yu-Xiang Zhang and Carles R. i Carceller and Morten Kjaergaard and Anders S. Sørensen},
journal= {arXiv preprint arXiv:2106.15744},
year = {2021}
}
Comments
main text (6 pages, 4 figures), supplemental material (8 pages, 5 figures, 1 table)