Experimental demonstration of modulation instability in an optical fiber with a periodic dispersion landscape

Droques, Maxime; Kudlinski, Alexandre; Bouwmans, Géraud; Martinelli, G.; Mussot, Arnaud

doi:10.1364/ol.37.004832

Cited by 77 publications

(89 citation statements)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The longitudinal spatial intensity oscillations of a multimode beam give rise to GPI and multiple sidebands that can be generated far away from the pump (shifts larger than 100 THz) [11,12]. This self-induced phase-matching mechanism is analogous to quasi-phase matched wave (QPM) generation in periodic amplified transmission systems or dispersion-managed fibers [13][14][15]. For a few-mode fiber (FMF) instead, the number of intermodal, nonlinear coupling terms is much smaller: the frequencies of parametrically generated waves can be obtained from the phase-matching conditions of IMFWM processes.…”

mentioning

confidence: 99%

Far-detuned cascaded intermodal four-wave mixing in a multimode fiber

et al. 2017

View full text Add to dashboard Cite

We demonstrate far-detuned parametric frequency conversion processes in a few mode graded-index optical fibers pumped by a Q-switched picosecond laser at 1064 nm. Through a detailed analytical and numerical analysis, we show that the multiple sidebands are generated through a complex cascaded process involving inter-modal four-wave mixing. The resulting parametric wavelength detuning spans in the visible down to 405 nm and in the nearinfrared up to 1355 nm. Multimode fibers (MMFs) recently have attracted renewed interest in the context of spatial-division multiplexing (SDM) for increasing the capacity of fiber-based communications [1]. Research on MMF led to new nonlinear spatiotemporal phenomena such as multimode solitons, geometric parametric instability (GPI), supercontinuum (SC) generation, and selfinduced beam cleaning [2][3][4][5][6][7][8][9][10][11][12]. Among MMFs, parabolic graded-index multimode fibers (GRIN-MMFs) have the unique property of supporting guided modes with equally spaced propagation constants and nearly identical group velocities [3,4]. These features enabled the observation of multimode solitons [5] and the associated generation of a set of discrete dispersive waves over an ultra-broadband range [6][7][8].In this context, much work has focused on the dynamics of inter-modal four-wave mixing (IMFWM) in MMFs, which allows for large frequency shifts (hundreds of THz) when compared with single-mode fibers (SMFs) [4,9,10]. When a large number of modes is initially excited in MMFs, the frequencies of the parametric lines can be determined through a collective approach involving the dynamics of the total field, as proposed by Longhi [11]. The longitudinal spatial intensity oscillations of a multimode beam give rise to GPI and multiple sidebands that can be generated far away from the pump (shifts larger than 100 THz) [11,12]. This self-induced phase-matching mechanism is analogous to quasi-phase matched wave (QPM) generation in periodic amplified transmission systems or dispersion-managed fibers [13][14][15]. For a few-mode fiber (FMF) instead, the number of intermodal, nonlinear coupling terms is much smaller: the frequencies of parametrically generated waves can be obtained from the phase-matching conditions of IMFWM processes. Mafi and co-workers recently revisited the theory of IMFWM in a GRIN-FMF for a degenerate spatial mode pump configuration, in which two pump photons are in the same spatial mode [3,16,17], and derived a new analytic formula for the parametric sideband frequencies, their modal composition, and associated conversion efficiency.In this Letter, we experimentally investigate IMFWM in a GRIN-FMF pumped in the normal dispersion regime at 1064 nm (282 THz). We report the observation of parametric sidebands ranging from the visible down to 405 nm to the nearinfrared up to 1355 nm, which is the largest frequency range observed to date in a FMF. The analytical phase-matching condition for IMFWM allows us to predict the position of the first observed spectral component, which is l...

show abstract

mentioning

confidence: 99%

Far-detuned cascaded intermodal four-wave mixing in a multimode fiber

et al. 2017

View full text Add to dashboard Cite

show abstract

“…(4) (see dashed vertical lines). The possibility of observing QPM-induced MI in such a situation, where a large set of spectral lines is generated, was experimentally confirmed in the work of Droques et al [5]. However, for an increasing level of dispersion amplitude oscillations (e.g., D amp = 1.7 ps/km/nm, case (b) of Fig.…”

Section: Influence Of the Amplitude Of The Dispersion Fluctuationmentioning

confidence: 80%

“…Nevertheless, we checked that these effects do not have a noticeable influence on the MI spectral dynamics that we are going to describe. MI induced by the longitudinal variations of chromatic dispersion has been theoretically investigated before in a wide range of configurations, ranging from sinusoidal profiles with a spatial period of a few tens of meters [5,9], up to dispersion-managed systems with periods of several kilometers [6,[12][13][14]. We consider in this contribution the specific case of DOF whose parameters are inspired by the previous numerical works which were carried out in the context of the transmission of high-speed telecommunication signals in dense dispersion managed links [15].…”

Section: Model and Situation Under Investigationmentioning

confidence: 99%

“…Indeed, thanks to the periodic dispersion landscape, which leads to quasi-phase-matching (QPM) of the nonlinear four-wave mixing (FWM) process, MI sidebands can be observed even in the regime of normal average GVD of a dispersion-oscillating optical fiber (DOF) [6][7][8]. Recent experimental works have confirmed the QPM-induced MI process in the normal GVD regime of microstructured DOF around 1 lm [5], as well as of non-microstructured highly nonlinear DOF at telecom wavelengths [9,10].…”

Section: Introductionmentioning

confidence: 98%

“…In nonlinear fiber optics, such a process has been demonstrated in fibers with anomalous, constant group velocity dispersion (GVD) [1], as well as in normal GVD fibers by enabling the fulfillment of the nonlinear phase-matching condition through either fourth order dispersion [2], birefringence or a multimodal structure [3,4]. More recently, a renewed experimental and theoretical interest in MI studies has been stimulated by the availability of fibers presenting a longitudinal and periodic modulation of their dispersion properties [5]. Indeed, thanks to the periodic dispersion landscape, which leads to quasi-phase-matching (QPM) of the nonlinear four-wave mixing (FWM) process, MI sidebands can be observed even in the regime of normal average GVD of a dispersion-oscillating optical fiber (DOF) [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Gain sideband splitting in dispersion oscillating fibers

Finot

Fang

Chembo

et al. 2014

Optical Fiber Technology

View full text Add to dashboard Cite

a b s t r a c tWe analyze the modulation instability spectrum in a varying dispersion optical fiber as a function of the dispersion oscillation amplitude. For large dispersion oscillations, we predict a novel sideband splitting into different sub-sidebands. The emergence of the new sidebands is observed whenever the classical perturbation analysis for parametric resonances predicts vanishing sideband amplitudes. The numerical results are in good quantitative agreement with Floquet or Bloch stability analysis of four-wave mixing in the periodic dispersion fiber. We have also shown that linear gain or loss may have a dramatic influence in reshaping the new sidebands.

show abstract

Supercontinuum Generation in Media with Sign‐Alternated Dispersion

Zia

Lüpken

Hellwig

et al. 2020

Laser & Photonics Reviews

View full text Add to dashboard Cite

When an ultrafast optical pulse with high intensity is propagating through transparent material a supercontinuum can be coherently generated by self-phase modulation, which is essential to many photonic applications in fibers and integrated waveguides. However, the presence of dispersion causes stagnation of spectral broadening past a certain propagation length, requiring an increased input peak power for further broadening. Overcoming such spectral stagnation will be key to achieve practical integrated supercontinuum devices. We present a concept to drive supercontinuum generation with significantly lower input power by counteracting spectral stagnation via repeatedly alternating the sign of group velocity dispersion along the propagation. We demonstrate the effect experimentally in dispersion alternating fiber in excellent agreement with modeling, revealing almost an order of magnitude reduced peak power compared to uniform dispersion. Calculations reveal a similar power reduction also with integrated optical waveguides, simultaneously with a significant increase of flat bandwidth, which is important for on-chip broadband photonics.

show abstract

Experimental demonstration of modulation instability in an optical fiber with a periodic dispersion landscape

Cited by 77 publications

References 12 publications

Far-detuned cascaded intermodal four-wave mixing in a multimode fiber

Far-detuned cascaded intermodal four-wave mixing in a multimode fiber

Gain sideband splitting in dispersion oscillating fibers

Supercontinuum Generation in Media with Sign‐Alternated Dispersion

Contact Info

Product

Resources

About