One-Dimensional Waveguide Coupled to Multiple Qubits: Photon-Photon Correlations
Abstract
For a one-dimensional (1D) waveguide coupled to two or three qubits, we show that the photon-photon correlations have a wide variety of behavior, with structure that depends sensitively on the frequency and on the qubit-qubit separation . We study the correlations by calculating the second-order correlation function in which the interference among the photons multiply scattered from the qubits causes rich structure. In one case, for example, transmitted and reflected photons are both bunched initially, but then become strongly anti-bunched for a long time interval. We first calculate the correlation function including non-Markovian effects and then show that a much simpler Markovian treatment, which can be solved analytically, is accurate for small qubit separation. As a result, the non-classical properties of microwaves in a 1D waveguide coupled to many superconducting qubits with experimentally accessible separation could be readily explored with our approach.
Cite
@article{arxiv.1308.6551,
title = {One-Dimensional Waveguide Coupled to Multiple Qubits: Photon-Photon Correlations},
author = {Yao-Lung L. Fang and Huaixiu Zheng and Harold U. Baranger},
journal= {arXiv preprint arXiv:1308.6551},
year = {2014}
}
Comments
11 pages, 6 figures. Journal version. Added one plot and the associated discussions and expanded the method in Appendix A