Real-Time Observation of the Buildup of Soliton Molecules

Liu, Xueming; Yao, Xiaoyan; Cui, Yudong

doi:10.1103/physrevlett.121.023905

Cited by 465 publications

(256 citation statements)

References 39 publications

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“…Figure a illustrates the Fourier transform of each single‐shot spectrum in Figure b, corresponding to a field autocorrelation of the momentary pulses, which traces the evolution of temporal separation between pulses . Figures b and 5c are enlargements of the A and B regions in Figure a, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…Ultrafast lasers with high repetition rate have many potential applications in multiple areas such as optical telecommunications, frequency metrology, high‐speed optical sampling, and data storage . Usually, fiber lasers have a fundamental repetition rate of tens to hundreds of MHz due to the difficulty of shortening the laser cavity . To increase the pulse repetition rate of fiber lasers, a less technically challenging and more convenient way is the harmonic mode‐locking (HML) scheme, where multiple pulses are evenly spaced in the cavity .…”

Section: Introductionmentioning

confidence: 99%

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Revealing the Buildup Dynamics of Harmonic Mode‐Locking States in Ultrafast Lasers

Liu

Pang

2019

Laser & Photonics Reviews

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206

101

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Harmonic mode‐locking (HML) is an important technique enabling the generation of high‐repetition‐rate ultrashort pulses. Using an emerging time‐stretch dispersive Fourier transform technique, the experimental observation of the entire buildup process of the passive HML state in an ultrafast fiber laser is reported here. It is unveiled that the whole process of HML buildup successively undergoes seven different ultrafast phases: raised relaxation oscillation, spectral beating behavior, birth of a giant pulse, self‐phase‐modulation‐induced instability, pulse splitting, repulsion and separation of multiple pulses, and a stable HML state. It is observed that the multiple HML pulses originate from a single‐pulse splitting phenomenon and a remarkable breathing behavior occurs at an early stage of the HML buildup process. The numerical results confirm that the effects of dispersive wave, gain depletion and recovery, and acoustic wave play key roles in the earlier, middle, and later stages of this HML buildup process, respectively; as well, the acoustic resonance in the single‐mode fiber stabilizes the final HML state of lasers.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Revealing the Buildup Dynamics of Harmonic Mode‐Locking States in Ultrafast Lasers

Liu

Pang

2019

Laser & Photonics Reviews

Self Cite

206

101

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“…In summary, soliton molecules can be found not only in the optical systems [2,4] but also in fluid systems, which may be applied for the oceanic surface and internal waves [29,30], plasma waves [35], electromagnetic waves in discrete transmission lines [36] and so on. The fluid model (1) is integrable only in three special cases involving the fifth order KdV equation, the SK equation and the KK equation.…”

Section: { } { }mentioning

confidence: 99%

“…Soliton molecules and bound states of solitons have been observed experimentally in optics [1][2][3][4] and predicted numerically in Bose-Einstein condensates [5]. On the other hand, solitons play a very important role in various modern scientific fields including fluids [6], plasmas [7], fibers [8], optics [9], complex networks [10], quantum field theory [11], gravity [12], Bose-Einstein condensates [13], atmospheric and oceanic dynamics [14] and so on.…”

mentioning

confidence: 99%

Soliton molecules and asymmetric solitons in three fifth order systems via velocity resonance

Sen-Yue

2020

J. Phys. Commun.

157

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Soliton molecules can be formed in some possible mechanisms both theoretically and experimentally. In this paper, we introduce a new mechanism, namely the velocity resonant, to find soliton molecules. Under the velocity resonance mechanism, two solitons can form a kink-antikink molecule, an asymmetric soliton, a two-peak soliton and/or a far away bounded molecule depended on the selections of the wave numbers and the distance between two solitons of a molecule. The results are exhibited via three well known fifth order integrable systems which serve as a general fluid model, as well as models many other physical fields.

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“…Through a dispersive medium, the TS-DFT builds up a mapping from the spectrum to the temporal domain pulse and a realtime optical spectrum analysis can be performed by combining the TS-DFT with a real-time oscilloscope 13 . The TS-DFT provides endless possibilities for comprehension of ultrafast physical phenomena, including optical rogue waves [14][15][16] , soliton explosions 17,18 , mode-locking build-up processes [19][20][21] and sophisticated soliton dynamics [22][23][24][25] . Herink et al successively resolved the modelocking build-up process 19 and soliton molecule formation process 22 of a Kerr-lens Ti: sapphire laser.…”

mentioning

confidence: 99%

Real-Time Observation of the Regime Transition Dynamics of Mode-Locked Fiber Lasers

Zhang

et al. 2019

IEEE Photon. Technol. Lett.

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Mode-locked lasers exhibit complex nonlinear dynamics. Precise observation of these dynamics will aid in understanding of the underlying physics and provide new insights for laser design and applications. The starting dynamics, from initial noise fluctuations to the mode-locking regime, have previously been observed directly by time-stretched transform-based real-time spectroscopy. However, the regime transition dynamics, which are essential processes in mode-locked lasers, have not yet been resolved because regime transition process tracking is very challenging. Here we demonstrate the first insight into the regime transition dynamics enabled by our design of a real-time programmable mode-locked fibre laser, in which different operating regimes can be achieved and switched automatically. The regime transition dynamics among initial noise fluctuations, Q-switching, fundamental mode-locking and harmonic mode-locking regimes have been observed and thoroughly analysed by both temporal and spectral means. These findings will enrich our understanding of the complex dynamics inside mode-locked lasers.

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Real-Time Observation of the Buildup of Soliton Molecules

Cited by 465 publications

References 39 publications

Revealing the Buildup Dynamics of Harmonic Mode‐Locking States in Ultrafast Lasers

Revealing the Buildup Dynamics of Harmonic Mode‐Locking States in Ultrafast Lasers

Soliton molecules and asymmetric solitons in three fifth order systems via velocity resonance

Real-Time Observation of the Regime Transition Dynamics of Mode-Locked Fiber Lasers

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