Coherence loss of partially mode-locked fibre laser

Gao, Lei; Zhu, Tao; Wabnitz, Stefan; Liu, Min; Huang, Wei

doi:10.1038/srep24995

Cited by 29 publications

(37 citation statements)

References 33 publications

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“…This trend is more apparent in a phase diagram for the ellipticity angle χ versus the spherical orientation angle ψ, which are calculated as follows Here, s1, s2, s3 are the stokes parameters of the laser SOP. At variance with the case of partial mode-locking [11], neither a bifurcation nor total turbulence can be identified here. As shown in Fig.…”

Section: Results and Discusioncontrasting

confidence: 62%

“…Typically, this behavior means that the proliferation time and decay time are the same, as it has been observed for the optical puff associated with the onset of optical turbulence [13]. The reason is that underlying physics of the two types of lasers are different: the evolution of the optical puff in a partially mode-locked fiber laser system is only associated with the presence of multiplemode-mixing [11,13]. Whereas the formation of an optical cluster in a dissipative fiber laser system is more complex, involving both nonlinearity, dispersion, filtering, and loss/gain.…”

Section: Results and Discusionmentioning

confidence: 83%

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Polarization dynamics of dissipative soliton fiber laser

Gao

Cao

Zhu

2019

Nonlinear Optics (NLO)

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Dissipative solitons emerge as stable pulse solutions of non-integrable and non-conservative nonlinear physical systems, owing to a balance of nonlinearity, dispersion, filtering, and loss/gain. At variance with conventional solitons, dissipative solitons exhibit extremely complex and striking dynamics, and their occurrence is more universal in far-from-equilibrium natural systems. Taking advantage of the techniques of the dispersive Fourier transform and time lens, the spatio-temporal transient dynamics of dissipative solitons emerging from a fiber laser have been characterized in terms of both their amplitude and phase. Yet, a full avenue of the buildup process of dissipative solitons is full of debris, for the lack of the polarization evolution information. Here, we characterize the probabilistic polarization distributions of the buildup of dissipative solitons in a net-normal dispersion fiber laser system, modelocked by single-wall carbon nanotubes. The laser system operates from random amplified spontaneous emission into a stable dissipative soliton state as the cavity gain is progressively increased. Correspondingly, the state of polarization of each spectral wavelength convergences towards a fixed point. To reveal the invariant polarization relationship among the various wavelength components of the laser output field, the phase diagram of the ellipticity angle and the spherical orientation angle are introduced. We find that the state of polarization of each filtered wavelength in the central wavelength region of the dissipative soliton evolves linearly across its spectrum, while the states of polarization in the two fronts of the spectrum are spatially varying. Increasing cavity gain leads to spectrum broadening, meanwhile, the polarizations of the new generated frequencies extend to be scattering. Further increasing pump power results into dissipative soliton explosions, upon which a new kind of polarization optical rogue waves is identified. Those experimental results provide a deeper insight into the transient dynamics of dissipative soliton fiber lasers.

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Section: Results and Discusioncontrasting

confidence: 62%

Section: Results and Discusionmentioning

confidence: 83%

Polarization dynamics of dissipative soliton fiber laser

Gao

Cao

Zhu

2019

Nonlinear Optics (NLO)

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“…DFT has been used for observing the generation of RWs in the NLP regime. 82,[121][122][123][124] However, it is important to note that not all the NLPs could be considered as RWs. When the pulse-energy distribution of the NLPs is always Gaussian profile, this pulse state may be not the RW regime.…”

Section: Rogue Waves Generated By Soliton Interactionmentioning

confidence: 99%

Recent progress on optical rogue waves in fiber lasers: status, challenges, and perspectives

et al. 2020

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Rogue waves (RWs) are rare, extreme amplitude, localized wave packets, which have received much interest recently in different areas of physics. Fiber lasers with their abundant nonlinear dynamics provide an ideal platform to observe optical RW formation. We review recent research progress on rogue waves in fiber lasers. Basic concepts of RWs and the mechanisms of RW generation in fiber lasers are discussed, along with representative experimental and theoretical results. The measurement methods for RW identification in fiber lasers are presented and analyzed. Finally, prospects for future RW research in fiber lasers are summarized.

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“…4). We inset a saturable absorber, which is fabricated by filling reduced graphene oxide flakes into cladding holes of a photonic crystal fiber, to detuning nonlinear phase for phase matching through adjusting the SOP of light.…”

Section: Resultsmentioning

confidence: 99%