Your search keyword '"Kibler, Bertrand"' showing total 16 results

1. Mitigating the Brillouin strain and temperature cross-sensitivity in heavily GeO2-doped-core optical fibers.

Author

Deroh, Moise, Sylvestre, Thibaut, Godet, Adrien, Maillotte, Hervé, Kibler, Bertrand, and Beugnot, Jean-Charles

Subjects

PHYSICS research, BRILLOUIN scattering, STRAIN sensors, OPTICAL fibers, WAVELENGTHS

Abstract

We demonstrate an athermal Brillouin strain sensor using heavily GeO2-doped optical fibers. We also report nonlinear evolution of Brillouin temperature sensitivity as a function of wavelength and strong Brillouin gain in these fibers. [ABSTRACT FROM AUTHOR]

Published

2023

2. 4D optical fibers thermally drawn from shape-memory polymers.

Author

Strutynski, Clément, Evrard, Marianne, Désévédavy, Frédéric, Gadret, Grégory, Brachais, Claire-Hélène, Kibler, Bertrand, and Smektala, Frédéric

Subjects

PHYSICS research, PHOTONICS, OPTICS, OPTICAL fibers, ROBOTICS

Abstract

Adaptative objects based on shape-memory materials are expected to significantly impact numerous technological sectors including optics and photonics. In this work, we demonstrate the manufacturing of shape-memory optical fibers from the thermal stretching of additively manufactured preforms. First, we show how standard commercially-available thermoplastics can be used to produce long continuously-structured microfilaments with shape-memory abilities. Shape recovery as well as programmability performances of such elongated objects are assessed. Next, we open the way for light-guiding multicomponent fiber architectures that are able to switch from temporary configurations back to user-defined programmed shapes. We strongly expect that such actuatable fibers with light-guiding abilities will trigger exciting progress of unprecedented smart devices in the areas of photonics, electronics, or robotics. [ABSTRACT FROM AUTHOR]

Published

2023

3. Complex interactions of breathers.

Author

Gelash, Andrey, Chabchoub, Amin, and Kibler, Bertrand

Subjects

NONLINEAR optical materials, OPTICAL fibers, NONLINEAR waves, WAVELENGTHS, RESONANCE

Abstract

We present our recent theoretical and experimental advancements in studying complex multiple nonlinear interactions of coherent solitary wave structures on unstable background – breathers. We use the focusing one-dimensional nonlinear Schrödinger equation (NLSE) as a theoretical model. First, we describe the nonlinear mutual interactions between a pair of co-propagative breathers called breather molecules. Then with the novel approach of breather interaction management, we adjust the initial positions and phases of several breathers to observe various desired wave states at controllable moments of evolution. Our experiments carried out on a light wave platform with a nearly conservative optical fiber system accurately reproduce the predicted dynamics. In addition, we consider generalizations of the scalar breathers theory to the vector two-component NLSE describing polarized light and show examples of resonance vector breathers transformations. [ABSTRACT FROM AUTHOR]

Published

2023

4. Review of tellurite glasses purification issues for mid‐IR optical fiber applications.

Author

Désévédavy, Frédéric, Strutynski, Clément, Lemière, Arnaud, Mathey, Pierre, Gadret, Grégory, Jules, Jean‐Charles, Kibler, Bertrand, and Smektala, Frédéric

Subjects

OPTICAL fibers, TELLURITES, SUPERCONTINUUM generation, OPTICAL materials, GLASS, WATER purification, QUANTUM cascade lasers

Abstract

We reviewed the tellurite glass purification studies performed over the last 20 years, in particular dealing with the mid‐infrared (mid‐IR) transmission performances. Best results are obtained under rich O2 atmosphere with platinum crucibles although Gibbs energy calculations show that other crucibles material are possible such as gold or alumina. From the point of view of the thermodynamics of involved oxidation reactions only, we identified the suitable conditions based on Gibbs energy calculations to be a synthesis temperature set above 900 K and a O2 pressure around 105 Pa. The performances of the different purification techniques were also compared. Finally, we analyzed the tellurite fibers recently optimized for mid‐IR which present low attenuation up to 4 µm allowing supercontinuum generation up to 5 µm. [ABSTRACT FROM AUTHOR]

Published

2020

5. Dispersion-Engineered Step-Index Tellurite Fibers for Mid-Infrared Coherent Supercontinuum Generation from 1.5 to 4.5 μm with Sub-Nanojoule Femtosecond Pump Pulses.

Author

Froidevaux, Paul, Lemière, Arnaud, Kibler, Bertrand, Désévédavy, Frédéric, Mathey, Pierre, Gadret, Grégory, Jules, Jean-Charles, Nagasaka, Kenshiro, Suzuki, Takenobu, Ohishi, Yasutake, and Smektala, Frédéric

Subjects

TELLURITES, FEMTOSECOND pulses, SUPERCONTINUUM generation

Abstract

Featured Application: Supercontinuum generation in novel infrared fibers from high-repetition-rate femtosecond mode-locked laser pulses provides mid-infrared radiation with very attractive features such as high coherence and spectral power density over an ultra-broad spectral range, thus opening new prospects for remote sensing applications, in particular through mid-infrared spectroscopy. Mid-infrared supercontinuum generation from 1.5 to 4.5 µm with sub-nanojoule femtosecond pump pulses is demonstrated by using a short segment of dispersion-engineered step-index tellurite fiber with very low OH content. Distinct group-velocity dispersion regimes in a simple design of step-index tellurite fiber are also reported, which allows to choose the nonlinear pulse propagation regime according to the required tailoring of the supercontinuum source. Numerical simulations based on the generalized nonlinear Schrödinger equation are used to determine optimized fiber parameters before experimental demonstrations. We also analyse the coherence properties of the resulting supercontinuum sources. [ABSTRACT FROM AUTHOR]

Published

2018

6. Nonlinear spectral shaping and optical rogue events in fiber-based systems

Author

Hammani, Kamal, Kibler, Bertrand, Fatome, Julien, Boscolo, Sonia, Genty, Goery, Dudley, John M., Millot, Guy, and Finot, Christophe

Subjects

*OPTICAL fibers, *NONLINEAR optics, *SOLITONS, *ROGUE waves, *WAVELENGTHS, *SPECTRUM analysis

Abstract

Abstract: We provide an overview of our recent work on the shaping and stability of optical continua in the long pulse regime. Fibers with normal group-velocity dispersion at all-wavelengths are shown to allow for highly coherent continua that can be nonlinearly shaped using appropriate initial conditions. In contrast, supercontinua generated in the anomalous dispersion regime are shown to exhibit large fluctuations in the temporal and spectral domains that can be controlled using a carefully chosen seed. A particular example of this is the first experimental observation of the Peregrine soliton which constitutes a prototype of optical rogue-waves. [Copyright &y& Elsevier]

Published

2012

7. Quasi-Phase-Matched Third Harmonic Generation in Optical Fibers Using Refractive-Index Gratings.

Author

Tarnowski, Karol, Kibler, Bertrand, Finot, Christophe, and Urbanczyk, Waclaw

Subjects

*OPTICAL fibers, *OPTICAL phase conjugation, *REFRACTIVE index, *ELECTRICAL harmonics, *DIFFRACTION gratings

Abstract

The purpose of this paper is to demonstrate the quasi-phase-matching of third harmonic generation process in optical fibers using refractive-index gratings. We compare conversion efficiency calculated with analytical coupled-modes theory and numerical approach employing a system of coupled generalized nonlinear Schrödinger equation. Moreover, we show that introducing the phase matching condition that takes into account the nonlinear contribution to propagation constants significantly increases the conversion efficiency by several orders of magnitude. Finally, we optimize the grating constant to maximize conversion efficiency. [ABSTRACT FROM PUBLISHER]

Published

2011

8. Optical Parabolic Pulse Generation and Applications.

Author

Finot, Christophe, Dudley, John M., Kibler, Bertrand, Richardson, David J., and Millot, Guy

Subjects

FIBER optics, OPTICAL fibers, PICOSECOND pulses, CONFIGURATION space, OPTICAL materials, OPTOELECTRONIC devices

Abstract

Parabolic pulses in optical fibers have stimulated an increasing number of applications. We review here the physics underlying the generation of such pulses as well as the results obtained in a wide range of experimental configurations. [ABSTRACT FROM AUTHOR]

Published

2009

9. 1.7–18 µm mid-infrared supercontinuum generation in a dispersion-engineered step-index chalcogenide fiber.

Author

Lemière, Arnaud, Bizot, Rémi, Désévédavy, Frédéric, Gadret, Grégory, Jules, Jean-Charles, Mathey, Pierre, Aquilina, Christophe, Béjot, Pierre, Billard, Franck, Faucher, Olivier, Kibler, Bertrand, and Smektala, Frédéric

Abstract

We demonstrate 1.7–18 µm mid-infrared coherent supercontinuum generation by means of the full transmission window of a unique dispersion-engineered step-index Ge-Se-Te fiber. Our study thus opens the entire molecular fingerprint region to future chalcogenide fiber platforms. [ABSTRACT FROM AUTHOR]

Published

2021

10. Discretized Conical Waves in Multimode Optical Fibers.

Author

Kibler, Bertrand and Béjot, Pierre

Subjects

*HEAD waves, *OPTICAL fibers, *NONLINEAR optical materials, *SINGLE-mode optical fibers, *SUPERCONTINUUM generation, *WAVE packets, *ULTRA-short pulsed lasers, *PLASTIC optical fibers

Abstract

Multimode optical fibers are essential in bridging the gap between nonlinear optics in bulk media and single-mode fibers. The understanding of the transition between the two fields remains complex due to intermodal nonlinear processes and spatiotemporal couplings, e.g., some striking phenomena observed in bulk media with ultrashort pulses have not yet been unveiled in such waveguides. Here we generalize the concept of conical waves described in bulk media towards structured media, such as multimode optical fibers, in which only a discrete and finite number of modes can propagate. Such propagation-invariant optical wave packets can be linearly generated, in the limit of superposed monochromatic fields, by shaping their spatiotemporal spectrum, whatever the dispersion regime and waveguide geometry. Moreover, they can also spontaneously emerge when a rather intense short pulse propagates nonlinearly in a multimode waveguide, their finite energy is also associated with temporal dispersion. The modal distribution of optical fibers then provides a discretization of conical emission (e.g., discretized X waves). Future experiments in multimode fibers could reveal different forms of dispersion-engineered conical emission and supercontinuum light bullets. [ABSTRACT FROM AUTHOR]

Published

2021

11. Higher-order modulation instability in optical fibers.

Author

Erkintalo, Miro, Hammani, Kamal, Kibler, Bertrand, Finot, Christophe, Akhmediev, Nail, Dudley, John M., and Genty, Goery

Abstract

We report on theoretical, numerical and experimental study of a new form of instability in a nonlinear fiber. This process of higher-order modulation instability arises from the nonlinear superposition of elementary instability dynamics. [ABSTRACT FROM PUBLISHER]

Published

2012

12. Temporal manipulation of period-2 polarization domain wall solitons in a nonlinear fiber Kerr resonator.

Author

Fatome, Julien, Berti, Nicolas, Kibler, Bertrand, Xu, Gang, Murdoch, Stuart G., Erkintalo, Miro, and Coen, Stéphane

Subjects

*SOLITONS, *RESONATORS, *DATA warehousing, *FIBERS, *PROOF of concept

Abstract

We report on the experimental demonstration of temporal manipulations of dissipative polarization domain wall solitons in a Kerr nonlinear resonator operated in a period-doubled configuration. Our experiments are performed in a coherently driven normally dispersive fiber ring cavity, in which polarization domains emerge in virtue of a spontaneous symmetry breaking phenomenon. The addition of a lumped birefringent defect into the cavity forces their polarization components to swap on a two-round-trip cycle, thus protecting them from the deleterious impact of the system's asymmetries. We exploit these symbiotic dynamics in proof-of-concept buffering experiments, in which these dissipative structures are addressed individually and temporally manipulated through phase-encoded perturbations imprinted onto the driving beam. Our results provide new insights into the practical exploitation of spontaneous symmetry breaking mechanisms and the use of two-component dissipative structures for all-optical data storage applications. • Exploitation of the spontaneous polarization symmetry breaking phenomenon in a normally dispersive fiber Kerr resonator. • Generation of highly robust polarization domain wall solitons operated in a period-doubled configuration (P2-PDWs). • Temporal manipulations of these dissipative polarization domain walls in a proof-of concept buffering experiment. [ABSTRACT FROM AUTHOR]

Published

2023

13. Management of OH absorption in tellurite optical fibers and related supercontinuum generation.

Author

Savelii, Inna, Desevedavy, Frederic, Jules, Jean-Charles, Gadret, Gregory, Fatome, Julien, Kibler, Bertrand, Kawashima, Hiroyasu, Ohishi, Yasutake, and Smektala, Frederic

Subjects

*ABSORPTION, *TELLURITES, *OPTICAL fibers, *SUPERCONTINUUM generation, *MICROFABRICATION, *TRANSPARENCY (Optics), *MICROSTRUCTURE

Abstract

Highlights: [•] Fabrication of low-OH content and low-loss tellurite optical fibers. [•] Incorporation of fluoride ions makes tellurite fibers transparent up to 4μm. [•] 2000nm bandwidth supercontinuum in suspended core microstructured tellurite fiber. [Copyright &y& Elsevier]

Published

2013

14. Breather Wave Molecules.

Author

Gang Xu, Gelash, Andrey, Chabchoub, Amin, Zakharov, Vladimir, and Kibler, Bertrand

Subjects

*NONLINEAR Schrodinger equation, *BOUND states, *OPTICAL fibers

Abstract

We present both a theoretical description and experimental observation of the nonlinear mutual interactions between a pair of copropagative breathers in the framework of the focusing one-dimensional nonlinear Schrödinger equation. As a general case, we show that the resulting bound state of breathers exhibits moleculelike behavior with quasiperiodic oscillatory dynamics (i.e., internal coherent interactions and pulsations), while for commensurate conditions the molecule oscillations become exactly periodic. Our theoretical model is confirmed by an experimental observation of shaped moleculelike breather light waves propagating in a nearly conservative optical fiber system. Our work sheds new light on the existence of localized wave structures and recurrence dynamics beyond the multisoliton complexes. [ABSTRACT FROM AUTHOR]

Published

2019

15. Phase evolution of Peregrine-like breathers in optics and hydrodynamics.

Author

Gang Xu, Hammani, Kamal, Chabchoub, Amin, Dudley, John M., Kibler, Bertrand, and Finot, Christophe

Subjects

*WATER waves, *OPTICAL fibers, *HYDRODYNAMICS

Abstract

We present a simultaneous study of the phase properties of rational breather waves generated in a water wave tank and in an optical fiber platform, namely, the Peregrine soliton and related second-order solution. Our analysis of experimental wave measurements makes use of standard demodulation and filtering techniques in hydrodynamics and more complex phase retrieval techniques in optics to quantitatively confirm analytical and numerical predictions. We clearly highlight a characteristic phase shift that is a multiple of π between the central pulsed part and the continuous background of rational breathers at their maximum compression. Moreover, we reveal a large longitudinal phase shift across the point of maximum compression. [ABSTRACT FROM AUTHOR]

Published

2019

16. Nonlinear spectral analysis of Peregrine solitons observed in optics and in hydrodynamic experiments.

Author

Randoux, Stéphane, Suret, Pierre, Chabchoub, Amin, Kibler, Bertrand, and El, Gennady

Subjects

*OPTICAL fibers, *HYDRODYNAMICS, *NONLINEAR waves

Abstract

The data recorded in optical fiber and in hydrodynamic experiments reported the pioneering observation of nonlinear waves with spatiotemporal localization similar to the Peregrine soliton are examined by using nonlinear spectral analysis. Our approach is based on the integrable nature of the one-dimensional focusing nonlinear Schrödinger equation (1D-NLSE) that governs at leading order the propagation of the optical and hydrodynamic waves in the two experiments. Nonlinear spectral analysis provides certain spectral portraits of the analyzed structures that are composed of bands lying in the complex plane. The spectral portraits can be interpreted within the framework of the so-called finite gap theory (or periodic inverse scattering transform). In particular, the number N of bands composing the nonlinear spectrum determines the genus g=N-1 of the solution that can be viewed as a measure of complexity of the space-time evolution of the considered solution. Within this setting the ideal, rational Peregrine soliton represents a special, degenerate genus 2 solution. While the fitting procedures previously employed show that the experimentally observed structures are quite well approximated by the Peregrine solitons, nonlinear spectral analysis of the breathers observed both in the optical fiber and in the water tank experiments reveals that they exhibit spectral portraits associated with more general, genus 4 finite-gap NLSE solutions. Moreover, the nonlinear spectral analysis shows that the nonlinear spectrum of the breathers observed in the experiments slowly changes with the propagation distance, thus confirming the influence of unavoidable perturbative higher-order effects or dissipation in the experiments. [ABSTRACT FROM AUTHOR]

Published

2018