Ultra-low timing jitter femtosecond laser technology (<i>Invited</i>)

Yihan Pi; Chunze Wang; Youjian Song; Minglie Hu

doi:10.3788/IRLA20201058

Infrared and Laser Engineering, Volume. 49, Issue 12, 20201058(2020)

Ultra-low timing jitter femtosecond laser technology (Invited)

Yihan Pi, Chunze Wang, Youjian Song^*, and Minglie Hu

Key Laboratory of Opto-electronic Information Science and Technology of Ministry of Education, School of Precision Instruments and Opto-electronics Engineering, Tianjin University, Tianjin 300072, China

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Figures & Tables(6)

Fig. 1. [in Chinese]

Fig. 2. [in Chinese]

Fig. 3. [in Chinese]

Fig. 4. [in Chinese]

Table 1.
Representative progress of low timing jitter femtosecond laser
低抖动飞秒激光器的相关研究进展

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Table 1.
Representative progress of low timing jitter femtosecond laser
低抖动飞秒激光器的相关研究进展

Laser source		Integrated timing jitter	Integrated Fourier frequency range	Measurement method	Research institute
Classification	Laser cavity parameter	Integrated timing jitter	Integrated Fourier frequency range	Measurement method	Research institute
注：表示该类激光器测得的最低定时抖动值 indicates the measured lowest timing jitter of lasers in this category
Er-doped fiber laser	194-MHz NPR，soliton mode- locking regime (2007)[47]	18 fs	[1 kHz–10 MHz]	PD	MIT
	3-GHz SESAM，soliton mode- locking regime (2009)[48]	19 fs	[10 kHz–40 MHz]	PD	MIT
	200-MHz NPR with spectral filter，stretched-pulse mode-locking regime (2010)[49]	17.4 fs	[1 kHz–10 MHz]	PD	Shanghai Jiao Tong University
	1-GHz SESAM，soliton mode- locking regime (2010)[50]	22 fs	[1 kHz–10 MHz]	PD	MIT
	80-MHz NPR，cavity dispersion (2011)[26]	0.07 fs*	[10 kHz–40 MHz]	BOC	KAIST
	80-MHz CNT-SA，cavity dispersion (2013)[51]	0.5 fs	[10 kHz–40 MHz]	BOC	KAIST
	463-MHz MoS2-SA，soliton mode- locking regime (2015)[52]	33 fs	[1 kHz–1 MHz]	PD	Shanghai Jiao Tong University
	80-MHz NPR，cavity dispersion (2015)[53]	0.7 fs	[10 kHz–10 MHz]	BOC	KAIST
	129-MHz NPR with spectral filter，cavity dispersion (2015)[54]	3.46 fs	[10 kHz–10 MHz]	BOC	KAIST
	75-MHz NALM，cavity dispersion ，soliton molecule (2018)[45]	0.83 fs	[10 Hz–2 MHz]	BOC	Tianjin University
	36.56 MHz NALM，soliton mode- locking regime (2019)[55]	7.3 fs	[10 kHz–1 MHz]	FDL	KAIST
	2.68 GHz SESAM，cavity dispersion (2019)[39]	82.5fs	[300 Hz-30 MHz]	PD	Xi'an Institute of Optics and Precision Mechanics of CAS
Yb-doped fiber Laser	80-MHz NPR，stretched-pulse mode- locking regime (2011)[20]	0.18 fs*	[10 kHz–40 MHz]	BOC	KAIST
	80-MHz NPR，soliton laser (2011)[20]	1.8 fs	[10 kHz–40 MHz]	BOC	KAIST
	80-MHz NPR，amplifier-similariton (2011)[20]	2.9 fs	[10 kHz–40 MHz]	BOC	KAIST
	80-MHz, NPR with spectral filter，cavity dispersion (2014)[23]	0.57 fs	[10 kHz–10 MHz]	BOC	Tianjin University
	10-MHz SESAM，all-PM，cavity dispersion (2016)[24]	5.9 fs	[10 kHz–5 MHz]	BOC	Tianjin University
	880 MHz NPR，stretched-pulse mode- locking regime (2018)[37]	10 fs	[30 kHz–5 MHz]	BOC	Peking University
Tm-doped fiber laser	690-MHz harmonic mode-locking NPR，soliton mode-locking regime (2015)[56]	6 ps	[100 Hz–1 MHz]	PD	Tsinghua University
	253 MHz SBR Tm/Ho fiber laser (2016)[57]	20 fs	[100 Hz–2 MHz]	PD	Boston University
	1.5 GHz SESAM (2018)[58]	940 fs	[10 Hz–1 MHz]	PD	South China University of Technology
Solid laser	80-MHz KLM Ti:sapphire laser (2012)[22]	0.013 fs*	[100 Hz–40 MHz]	BOC	MIT
	100-MHz SESAM Cr:LiSAF laser (2012)[31]	0.03 fs	[10 kHz–50 MHz]	BOC	MIT
	100-MHz, SESAM, Er:Yb-glass laser (2013)[32]	0.083 fs	[10 kHz–50 MHz]	BOC	CSEM
	500-MHz SESAM Er:Yb-glass laser (2015)[25]	0.016 fs	[10 kHz–250 MHz]	OH	University of Colorado
Semiconductor laser	10 GHz SCOWA-based harmonically mode-locked nested cavity laser (2018)[59]	3.4 fs	[10 Hz,100 MHz]	PD	University of Central Florida
	21 GHz InAs/InP quantum dash laser (2018)[41]	400 fs	[10 kHz,100 MHz]	PD	University College Cork
	19 GHz integrated heterogeneous silicon/III-V colliding pulse mode-locked laser (2018)[42]	1.2 ps	[100 kHz,100 MHz]	PD	University of California
Optical Microresonator	22 GHz silica microcomb (2020)[43]	2.6 fs*	[10 kHz–3 MHz]	FDL	KAIST

Table 2.
Timing jitter of commercial femtosecond laser
商用飞秒激光器的定时抖动

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Table 2.
Timing jitter of commercial femtosecond laser
商用飞秒激光器的定时抖动

Laser source	Integrated timing jitter	Integrated Fourier frequency range	Company
Figure 9 fiber laser	<2 fs	[10 kHz–10 MHz]	Menlo System
Figure 9 Er- fiber laser^[34]	0.04 fs	[10 kHz–10 MHz]	IMRA America
MENHIR-1550	≤30 fs	[1 kHz–10 MHz]	MenHir Photonics
ORIGAMI 5-40	<30 fs	[1 kHz–10 MHz]	NKT Photonics

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Yihan Pi, Chunze Wang, Youjian Song, Minglie Hu. Ultra-low timing jitter femtosecond laser technology (Invited)[J]. Infrared and Laser Engineering, 2020, 49(12): 20201058

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Paper Information

Category: Advanced Laser Technology

Received: Sep. 18, 2020

Accepted: --

Published Online: Jan. 14, 2021

The Author Email: Song Youjian (宋有建（1981-）)

DOI:10.3788/IRLA20201058

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology

Table 1. Representative progress of low timing jitter femtosecond laser低抖动飞秒激光器的相关研究进展

Table 1. Representative progress of low timing jitter femtosecond laser低抖动飞秒激光器的相关研究进展

Table 2. Timing jitter of commercial femtosecond laser商用飞秒激光器的定时抖动

Table 2. Timing jitter of commercial femtosecond laser商用飞秒激光器的定时抖动

Table 1.
Representative progress of low timing jitter femtosecond laser
低抖动飞秒激光器的相关研究进展

Table 1.
Representative progress of low timing jitter femtosecond laser
低抖动飞秒激光器的相关研究进展

Table 2.
Timing jitter of commercial femtosecond laser
商用飞秒激光器的定时抖动

Table 2.
Timing jitter of commercial femtosecond laser
商用飞秒激光器的定时抖动