Search results for "Supercontinuum"

showing 8 items of 128 documents

Third-harmonic generation in optical microfibers: From silica experiments to highly nonlinear glass prospects

2012

International audience; Using optical microfibers, phase matching between different propagation modes allows for third-harmonic generation (THG). After detailing the relevant phase matching conditions and overlap integrals, we provide a comparison between THG effective efficiencies in silica and tellurite glasses. We also explain the relatively easy, wideband, conversion that we observe experimentally in silica glass microfibers, from 155 mu m to the green, by the geometry of the tapering region.

business.product_categoryMaterials scienceSilica glassTapering02 engineering and technology01 natural sciences010309 opticsOptics0103 physical sciencesMicrofiberElectrical and Electronic EngineeringPhysical and Theoretical ChemistryWidebandPhase matching[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]SUPERCONTINUUM GENERATIONbusiness.industry3RD HARMONIC-GENERATION021001 nanoscience & nanotechnologyAtomic and Molecular Physics and OpticsElectronic Optical and Magnetic MaterialsNonlinear system[ PHYS.PHYS.PHYS-AO-PH ] Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]Third harmonic0210 nano-technologybusinessFIBERS
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Supercontinuum generation in chalcogenide: application to gas spectroscopy in atmospheric band III

2023

This thesis work aims to contribute to the development of new fiber sources emitting over a wide range of wavelengths in the IR, in particular to detect greenhouse gases in the mid-infrared range. Our spectroscopy results with nitrous oxide N2O and methane CH4 are obtained in band III. To achieve this, the generation of supercontinuum (SC) covering band III was made possible by using chalcogenide optical fibers, purified and free of highly toxic elements according to REACH regulations, in particular arsenic and antimony. The fibrable vitreous composition belonging to the Ge-Se-Te ternary system fits perfectly into the context of sustainable development, it is the one that has been identifie…

chalcogénureschalcogenideoptical fiberinfrared[CHIM] Chemical Sciencessupercontinuum large bandefibre optiquebroadband supercontinuumcapteur de gazinfrarougegas sensor[PHYS] Physics [physics]
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Chalcogenide Fibers for Mid-IR Light Generation: Potentialities and Drawbacks of the Microstructured Design in Sulfide Waveguides

2014

We study optical and structural aging in As2S3 microstructured optical fibers, submitted to room atmosphere that may have, among others, an impact on mid-infrared supercontinuum generation.

chemistry.chemical_classificationPHOSFOSOptical fiberMaterials scienceSulfidebusiness.industryChalcogenideMicrostructured optical fiberlaw.inventionSupercontinuumchemistry.chemical_compoundOpticsZero-dispersion wavelengthchemistrylawOptoelectronicsbusinessPhotonic-crystal fiberAdvanced Solid State Lasers
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3.5-μm bandwidth mid-infrared supercontinuum generation in a 2-cm long suspended-core chalcogenide fiber

2014

A supercontinuum source extending from 0.6 to 4.1 µm has been successfully generated in a 2-cm long As2S3 chalcogenide suspended-core fiber by means of a nJ-level 200-fs pumping at 2.5 µm.

chemistry.chemical_compoundOpticsMaterials sciencechemistrybusiness.industryChalcogenideBandwidth (signal processing)Mid infraredOptoelectronicsbusinessSelf-phase modulationSupercontinuumPhotonic-crystal fiberAdvanced Photonics
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Octave Spanning Supercontinuum in Titanium Dioxide Waveguides

2018

International audience; We report on the experimental generation of an octave-spanning supercontinuum in a 2.2 cm-long titanium dioxide optical waveguide with two zero dispersion wavelengths. The resulting on-chip supercontinuum reaches the visible wavelength range as well as the mid-infrared region by using a femtosecond fiber laser pump at 1.64 µm.

integrated optics; supercontinuum generation; titanium dioxidePhysics::Optics02 engineering and technologyFemtosecond fiber laser01 natural sciences7. Clean energylcsh:Technologylaw.inventionlcsh:Chemistrychemistry.chemical_compoundlawDispersion (optics)General Materials ScienceInstrumentationlcsh:QH301-705.5ComputingMilieux_MISCELLANEOUSFluid Flow and Transfer Processes[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics][ PHYS.PHYS.PHYS-OPTICS ] Physics [physics]/Physics [physics]/Optics [physics.optics]General Engineering021001 nanoscience & nanotechnologylcsh:QC1-999Computer Science ApplicationsWavelengthintegrated opticsFemtosecondOptoelectronicsIntegrated optics0210 nano-technologyVisible spectrum[PHYS.PHYS.PHYS-OPTICS] Physics [physics]/Physics [physics]/Optics [physics.optics]Materials scienceAstrophysics::Cosmology and Extragalactic AstrophysicsOctave (electronics)010309 optics0103 physical sciencesSelf-phase modulationsupercontinuum generationbusiness.industrytitanium dioxidelcsh:TProcess Chemistry and TechnologyLaserSupercontinuumchemistrylcsh:Biology (General)lcsh:QD1-999lcsh:TA1-2040Titanium dioxidebusinesslcsh:Engineering (General). Civil engineering (General)Refractive indexlcsh:PhysicsApplied Sciences
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Supercontinuum Generation and Intermodal Four-Wave Mixing in a Step-Index Few-Mode Fibre

2019

International audience; The complex spatiotemporal dynamics of nonlinear light propagation in multimode fibers (MMFs) has recently witnessed a renewed interest because of their experimental realization in emerging key areas of laser physics and fiber optics [1]. Specifically, MMFs have a number of linear and nonlinear optical properties that make them very attractive to investigate new spatiotemporal effects fundamentally different from standard single-mode fibers. These include the observation of multimode solitons [2], intermodal four-wave mixing (FWM) [3], geometric parametric instabilities [4], spatial beam self-cleaning [5], and the generation of supercontinuum (SC) light when pumping …

lcsh:Applied optics. Photonics[PHYS.PHYS.PHYS-OPTICS] Physics [physics]/Physics [physics]/Optics [physics.optics]Optical fiberMaterials scienceSilica fiber[SPI.OPTI] Engineering Sciences [physics]/Optics / PhotonicComputer Networks and CommunicationsPhysics::Optics02 engineering and technology01 natural scienceslaw.invention[SPI.MAT]Engineering Sciences [physics]/Materials010309 opticsFour-wave mixingsymbols.namesakelaw0103 physical sciences[PHYS.COND]Physics [physics]/Condensed Matter [cond-mat]010306 general physicsComputingMilieux_MISCELLANEOUS[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]Multi-mode optical fiberSidebandbusiness.industrylcsh:TA1501-1820021001 nanoscience & nanotechnologyQ-switchingAtomic and Molecular Physics and OpticsSupercontinuumWavelengthPicosecondsymbols[SPI.OPTI]Engineering Sciences [physics]/Optics / PhotonicOptoelectronics[ SPI.OPTI ] Engineering Sciences [physics]/Optics / Photonic0210 nano-technologybusinessRaman scattering
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A universal optical all-fiber omnipolarizer

2012

International audience; Wherever the polarization properties of a light beam are of concern, polarizers and polarizing beamsplitters (PBS) are indispensable devices in linear-, nonlinear- and quantum-optical schemes. By the very nature of their operation principle, transformation of incoming unpolarized or partially polarized beams through these devices introduces large intensity variations in the fully polarized outcoming beam(s). Such intensity fluctuations are often detrimental, particularly when light is post-processed by nonlinear crystals or other polarization-sensitive optic elements. Here we demonstrate the unexpected capability of light to self-organize its own state-of-polarizatio…

optical fiberOptical fiberNonlinear optics02 engineering and technologypolarization control01 natural sciencesArticlelaw.invention010309 optics020210 optoelectronics & photonicsOpticslaw0103 physical sciences0202 electrical engineering electronic engineering information engineeringLight beamstimulated brillouin-cattering polarization control supercontinuum generationsupercontinuum generationPhysics[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]Multidisciplinary[ PHYS.PHYS.PHYS-OPTICS ] Physics [physics]/Physics [physics]/Optics [physics.optics]business.industryNonlinear opticsPolarizerPolarization (waves)stimulated brillouin-catteringNonlinear systemAll fiberTelecommunicationsbusinessBeam (structure)
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Measurement of the soliton number in guiding media through continuum generation.

2020

No general approach is available yet to measure directly the ratio between chromatic dispersion and the nonlinear coefficient, and hence the soliton number for a given optical pulse, in an arbitrary guiding medium. Here we solve this problem using continuum generation. We experimentally demonstrate our method in polarization-maintaining and single-mode fibers with positive and negative chromatic dispersion. Our technique also offers new opportunities to determine the chromatic dispersion of guiding media over a broad spectral range while pumping at a fixed wavelength. (C) 2020 Optical Society of America

optical fiberOptical fiberPhysics::Optics02 engineering and technology01 natural scienceslaw.invention010309 opticschromatic dispersionOptics:FÍSICA [UNESCO]law0103 physical sciencesDispersion (optics)supercontinuum generationPhysicsCONTINUOUS-WAVE MEASUREMENT; PHASE-MODULATION METHOD; OPTICAL-FIBERS; SUPERCONTINUUM GENERATION; REFRACTIVE-INDEX; DISPERSION; COEFFICIENT; INTERFEROMETER; NONLINEARITY; COMPRESSIONsoliton propagationContinuum (measurement)business.industrynonlinear opticsUNESCO::FÍSICANonlinear coefficient021001 nanoscience & nanotechnologyAtomic and Molecular Physics and OpticsNonlinear systemWavelengthInterferometry0210 nano-technologybusinessRefractive indexOptics letters
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