Gaussian functions are optimal for waveguided nonlinear-quantum-optical processes
Abstract
Many nonlinear optical technologies require the two-mode spectral amplitude function that describes them---the \emph{joint spectral amplitude} (JSA)---to be separable. We prove that the JSA factorizes \emph{only} when the incident pump field and phase-matching function are Gaussian functions. We show this by mapping our problem to a known result, in continuous variable quantum information, that only squeezed states remain unentangled when combined on a beam splitter. We then conjecture that only a squeezed state minimizes entanglement when sent through a beam splitter with another pre-specified ket. This implies that to maximize JSA separability when one of the (pump or nonlinear medium) functions is non-Gaussian, the other function \emph{must} be Gaussian. This answers an outstanding question about optimal design of certain nonlinear processes, and is of practical interest to researchers using waveguide nonlinear optics to generate and manipulate quantum light.
Cite
@article{arxiv.1805.06868,
title = {Gaussian functions are optimal for waveguided nonlinear-quantum-optical processes},
author = {Nicolás Quesada and Agata M. Brańczyk},
journal= {arXiv preprint arXiv:1805.06868},
year = {2018}
}
Comments
8 pages main text, 6 pages of appendices, 5 figures