Real-time transition dynamics and stability of chip-scale dispersion-managed frequency microcombs

Femtosecond mode-locked laser frequency combs have served as the cornerstone in precision spectroscopy, all-optical atomic clocks, and measurements of ultrafast dynamics. Recently frequency microcombs based on nonlinear microresonators have been examined, exhibiting remarkable precision approaching...

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Veröffentlicht in:	Light, science & applications science & applications, 2020-04, Vol.9 (1), p.52-52, Article 52
Hauptverfasser:	Li, Yongnan, Huang, Shu-Wei, Li, Bowen, Liu, Hao, Yang, Jinghui, Vinod, Abhinav Kumar, Wang, Ke, Yu, Mingbin, Kwong, Dim-Lee, Wang, Hui-Tian, Wong, Kenneth Kin-Yip, Wong, Chee Wei
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Sprache:	eng
Schlagworte:	140/125 639/624 639/766 Applied and Technical Physics Atomic Classical and Continuum Physics Lasers Letter Molecular Optical and Plasma Physics Optical Devices Optics Photonics Physics Physics and Astronomy Spectroscopy
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creator	Li, Yongnan Huang, Shu-Wei Li, Bowen Liu, Hao Yang, Jinghui Vinod, Abhinav Kumar Wang, Ke Yu, Mingbin Kwong, Dim-Lee Wang, Hui-Tian Wong, Kenneth Kin-Yip Wong, Chee Wei
description	Femtosecond mode-locked laser frequency combs have served as the cornerstone in precision spectroscopy, all-optical atomic clocks, and measurements of ultrafast dynamics. Recently frequency microcombs based on nonlinear microresonators have been examined, exhibiting remarkable precision approaching that of laser frequency combs, on a solid-state chip-scale platform and from a fundamentally different physical origin. Despite recent successes, to date, the real-time dynamical origins and high-power stabilities of such frequency microcombs have not been fully addressed. Here, we unravel the transitional dynamics of frequency microcombs from chaotic background routes to femtosecond mode-locking in real time, enabled by our ultrafast temporal magnifier metrology and improved stability of dispersion-managed dissipative solitons. Through our dispersion-managed oscillator, we further report a stability zone that is more than an order-of-magnitude larger than its prior static homogeneous counterparts, providing a novel platform for understanding ultrafast dissipative dynamics and offering a new path towards high-power frequency microcombs.
doi_str_mv	10.1038/s41377-020-0290-3
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subjects	140/125 639/624 639/766 Applied and Technical Physics Atomic Classical and Continuum Physics Lasers Letter Molecular Optical and Plasma Physics Optical Devices Optics Photonics Physics Physics and Astronomy Spectroscopy
title	Real-time transition dynamics and stability of chip-scale dispersion-managed frequency microcombs
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