Stability of laser cavity-solitons for metrological applications
Laser cavity-solitons can appear in systems comprised of a nonlinear microcavity nested within an amplifying fiber loop. These states are robust and self-emergent and constitute an attractive class of solitons that are highly suitable for microcomb generation. Here, we present a detailed study of the free-running stability properties of the carrier frequency and repetition rate of single solitons, which are the most suitable states for developing robust ultrafast and high repetition rate comb sources. We achieve free-running fractional stability on both optical carrier and repetition rate (i.e., 48.9 GHz) frequencies on the order of 10−9 for a 1 s gate time. The repetition rate results compare well with the performance of state-of-the-art (externally driven) microcomb sources, and the carrier frequency stability is in the range of performance typical of modern free-running fiber lasers. Finally, we show that these quantities can be controlled by modulating the laser pump current and the cavity length, providing a path for active locking and long-term stabilization.
Funding
Industrial Pathway to Micro-Comb Lasers
Engineering and Physical Sciences Research Council
Find out more...Development of highly efficient, portable, and fiber-integrated photonic platforms based on micro-resonators
Innovate UK
Find out more...ERC (851758 TELSCOMBE)
DSTL (DSTLX1000142078)
Leverhulme Trust (ECF-2020-537 and ECF- 2022-710)
ERC (TIMING 725046)
NSERC (Strategic, and Discovery Grants Schemes)
Canada Research Chair
MESI PSR-SIIRI Initiatives in Quebec
History
School
- Science
Department
- Physics
Published in
Applied Physics LettersVolume
122Issue
12Publisher
AIP PublishingVersion
- VoR (Version of Record)
Rights holder
© Author(s)Publisher statement
This is an Open Access article published by AIP Advances. All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).Acceptance date
2023-02-03Publication date
2023-03-20Copyright date
2023ISSN
0003-6951eISSN
1077-3118Publisher version
Language
- en