Quantum diffusion of microcavity solitons
Abstract
Coherently-pumped (Kerr) solitons in an ideal optical microcavity are expected to undergo random quantum motion that determines fundamental performance limits in applications of soliton microcombs. Here, this diffusive motion and its impact on Kerr soliton timing jitter is studied experimentally. Typically hidden below technical noise contributions, the quantum limit is discerned by measuring counter-propagating solitons. Their relative motion features only weak interactions and also presents excellent common mode suppression of technical noise. This is in strong contrast to co-propagating solitons which are found to have relative timing jitter well below the quantum limit of a single soliton on account of strong mutual motion correlation. Good agreement is found between theory and experiment. The results establish the fundamental limits to timing jitter in soliton microcombs and provide new insights on multi-soliton physics
Cite
@article{arxiv.2003.06685,
title = {Quantum diffusion of microcavity solitons},
author = {Chengying Bao and Myoung-Gyun Suh and Boqiang Shen and Kemal Şafak and Anan Dai and Heming Wang and Lue Wu and Zhiquan Yuan and Qi-Fan Yang and Andrey B. Matsko and Franz X. Kärtner and Kerry J. Vahala},
journal= {arXiv preprint arXiv:2003.06685},
year = {2023}
}