Aberration-corrected quantum temporal imaging system
Abstract
We describe the design of a temporal imaging system that simultaneously reshapes the temporal profile and converts the frequency of a photonic wavepacket, while preserving its quantum state. A field lens, which imparts a temporal quadratic phase modulation, is used to correct for the residual phase caused by field curvature in the image, thus enabling temporal imaging for phase-sensitive quantum applications. We show how this system can be used for temporal imaging of time-bin entangled photonic wavepackets and compare the field lens correction technique to systems based on a temporal telescope and far-field imaging. The field-lens approach removes the residual phase using four dispersive elements. The group delay dispersion (GDD) is constrained by the available bandwidth by , where is the temporal width of the waveform associated with the dispersion . This is compared to the much larger dispersion required to satisfy the Fraunhofer condition in the far field approach.
Cite
@article{arxiv.1303.2100,
title = {Aberration-corrected quantum temporal imaging system},
author = {Yunhui Zhu and Jungsang. Kim and Daniel J. Gauthier},
journal= {arXiv preprint arXiv:1303.2100},
year = {2013}
}
Comments
8 pages, 6 figures