0000000001248519

AUTHOR

Vincent Laude

showing 22 related works from this author

Notice of Removal: Stochastic generation of the phononic band structure of lossy and infinite crystals

2017

The concept of the band structure is central to the field of phononic crystals. Indeed, capturing the dispersion of Bloch waves — the eigenmodes of propagation in periodic media — gives invaluable information on allowed propagation modes, their phase and group velocities, local resonances, and band gaps. Band structures are usually obtained by solving an eigenvalue problem defined on a closed and bounded domain, which results in a discrete spectrum. There are at least two cases, however, that cannot be reduced to a simple eigenvalue problem: first, when materials showing dispersive loss are present and second, when the unit-cell extends beyond any bound, as in the case of phononic crystal o…

PhysicsField (physics)Band gapBounded functionQuantum mechanicsPhase (waves)Electronic band structureDispersion (water waves)Eigenvalues and eigenvectorsBloch wave2017 IEEE International Ultrasonics Symposium (IUS)
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Surface-Wave Coupling to Single Phononic Subwavelength Resonators

2017

International audience; We propose to achieve manipulation of mechanical vibrations at the micron scale by exploiting the interaction of individual, isolated mechanical resonators with surface acoustic waves. We experimentally investigate a sample consisting of cylindrical pillars individually grown by focused-ion-beam-induced deposition on a piezoelectric substrate, exhibiting different geometrical parameters and excited by a long-wavelength surface elastic wave. The mechanical displacement is strongly confined in the resonators, as shown by field maps obtained by laser scanning interferometry. A tenfold displacement field enhancement compared to the vibration at the surface is obtained, r…

PhysicsCouplingSurface (mathematics)[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph][SPI.OTHER]Engineering Sciences [physics]/Other[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]business.industryElastic energyGeneral Physics and Astronomy02 engineering and technology021001 nanoscience & nanotechnology01 natural sciences[SPI.MAT]Engineering Sciences [physics]/MaterialsVibrationResonatorOpticsSurface wave0103 physical sciences[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics010306 general physics0210 nano-technologybusinessMicroscale chemistryPlasmon
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Phononic crystals: Harnessing the propagation of sound, elastic waves, and phonons

2016

Comptes Rendus Physique - In Press.Proof corrected by the author Available online since jeudi 3 mars 2016

Physicsgeographygeography.geographical_feature_categoryPhononAcousticsGeneral EngineeringEnergy Engineering and Power Technology02 engineering and technologyMars Exploration ProgramPhysics and Astronomy(all)021001 nanoscience & nanotechnology01 natural sciences0103 physical sciencesAcoustic metamaterials010306 general physics0210 nano-technologySound (geography)Comptes Rendus Physique
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Two Methods to Broaden the Bandwidth of a Nonlinear Piezoelectric Bimorph Power Harvester

2017

We propose two methods to broaden the operation bandwidth of a nonlinear pinned–pinned piezoelectric bimorph power harvester. The energy-scavenging structure consists of a properly poled and electroded flexible bimorph with a metallic layer in the middle, and is subjected to flexural vibration. Nonlinear effects at large deformations near resonance are considered by taking the in-plane extension of the bimorph into account. The resulting output powers are multivalued and exhibit jump phenomena. Two methods to broaden the operation bandwidth are proposed: The first method is to extend the operation frequency to the left single-valued region through optimal design. The second method is to exc…

Engineeringbusiness.industryBandwidth (signal processing)General Engineering02 engineering and technology021001 nanoscience & nanotechnology01 natural sciencesNonlinear systemPiezoelectric bimorph0103 physical sciencesElectronic engineering0210 nano-technologybusiness010301 acousticsJournal of Vibration and Acoustics
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Multiple low-frequency broad band gaps generated by a phononic crystal of periodic circular cavity sandwich plates

2017

Abstract We propose a new type of phononic crystal (PnC) composed of a periodic alternation of circular cavity sandwich plates. In the low-frequency regime, the crystal can modulate the propagation of flexural waves. Governing equations are deduced basing on the classical theory of coupled extensional and flexural vibrations of plates. The dispersion relation of the infinite PnC is calculated by combining the transfer matrix method with Bloch theory. The dynamic response of the PnC with finite unit cells is further studied with finite element analysis. An experiment is carried out to demonstrate the performance of the PnC in vibration isolation. Numerical results and experimental results bo…

010302 applied physicsMaterials scienceBand gapbusiness.industryAttenuationTransfer-matrix method (optics)02 engineering and technologyStructural engineeringLow frequency021001 nanoscience & nanotechnology01 natural sciencesFinite element methodComputational physicsCrystalVibration isolationDispersion relation0103 physical sciencesCeramics and Composites0210 nano-technologybusinessCivil and Structural EngineeringComposite Structures
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Observation of topological gravity-capillary waves in a water wave crystal

2019

The discovery of topological phases of matter, initially driven by theoretical advances in quantum condensed matter physics, has been recently extended to classical wave systems, reaching out to a wealth of novel potential applications in signal manipulation and energy concentration. Despite the fact that many realistic wave media (metals at optical frequencies, polymers at ultrasonic frequencies) are inherently dispersive, topological wave transport in photonic and phononic crystals has so far been limited to ideal situations and proof-of-concept experiments involving dispersionless media. Here, we report the first experimental demonstration of topological edge states in a classical water …

Capillary waveWave propagationFOS: Physical sciencesGeneral Physics and AstronomyInsulator (electricity)Topology01 natural sciences010305 fluids & plasmas[SPI.MAT]Engineering Sciences [physics]/MaterialsMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciences[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics010306 general physicsDispersion (water waves)QuantumPhysics[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]Condensed Matter - Mesoscale and Nanoscale Physicsbusiness.industryFluid Dynamics (physics.flu-dyn)Valley PhysicsPhysics - Fluid DynamicsTopological InsulatorsWater wavesTopological insulatorUltrasonic sensorPhotonicsbusiness
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Guidance of surface elastic waves along a linear chain of pillars

2016

International audience; The propagation of surface elastic waves, or surface phonons, is considered along a linear and periodic chain of cylindrical pillars sitting on a semi-infinite solid substrate. A variety of guided modes, some of them exhibiting a very low group velocity, are shown to exist at frequencies close to the resonance frequencies of the pillars. Although the pillar diameter is typically smaller than half the relevant wavelength, lateral radiation on the surface is found to be canceled. Surface guidance is explained by the hybridization of the resonating pillars with the continuum of elastic waves of the substrate.

[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]010302 applied physicsMaterials scienceCondensed matter physicsbusiness.industryPhononPillarGeneral Physics and Astronomy02 engineering and technologyRadiation021001 nanoscience & nanotechnology01 natural scienceslcsh:QC1-999[SPI.MAT]Engineering Sciences [physics]/MaterialsWavelengthLove waveSolid substrateAcoustic wave propagationOptics0103 physical sciencesGroup velocity[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics0210 nano-technologybusinesslcsh:PhysicsAIP Advances
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Guiding and splitting Lamb waves in coupled-resonator elastic waveguides

2018

Abstract We investigate experimentally Lamb wave propagation in coupled-resonator elastic waveguides (CREWs) formed by a chain of cavities in a two-dimensional phononic crystal slab with cross holes. Wide complete bandgaps, extending from 53 to 88 kHz, are first measured in a finite phononic crystal slab sample. A straight waveguide and a wave splitting circuit with 90° bends are then designed, fabricated and measured. Elastic Lamb waves are excited by a piezoelectric patch attached to one side of the phononic slab and detected using a scanning vibrometer. Strongly confined guiding and splitting at waveguide junctions are clearly observed for several guided waves. Numerical simulations are …

010302 applied physicsMaterials sciencebusiness.industryPhysics::Optics02 engineering and technology021001 nanoscience & nanotechnology01 natural sciencesPiezoelectricitylaw.inventionCrystalResonatorLamb wavesOpticslaw0103 physical sciencesDispersion (optics)Ceramics and CompositesSlab0210 nano-technologybusinessLaser Doppler vibrometerWaveguideCivil and Structural EngineeringComposite Structures
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Acoustic Topological Circuitry in Square and Rectangular Phononic Crystals

2021

International audience; We systematically engineer a series of square and rectangular phononic crystals to create experimental realizations of complex topological phononic circuits. The exotic topological transport observed is wholly reliant upon the underlying structure which must belong to either a square or rectangular lattice system and not to any hexagonal-based structure. The phononic system chosen consists of a periodic array of square steel bars which partitions acoustic waves in water over a broadband range of frequencies (∼0.5MHz). An ultrasonic transducer launches an acoustic pulse which propagates along a domain wall, before encountering a nodal point, from which the acoustic si…

[SPI.NANO] Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics[PHYS.MPHY]Physics [physics]/Mathematical Physics [math-ph]Crystal systemFOS: Physical sciencesGeneral Physics and Astronomy02 engineering and technology[SPI.MAT] Engineering Sciences [physics]/MaterialsTopology01 natural sciencesSignal09 EngineeringSquare (algebra)Physics AppliedWAVE-GUIDE[SPI.MAT]Engineering Sciences [physics]/MaterialsDESIGNcond-mat.mes-hallMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciences[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics010306 general physicsElectronic circuit[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]Physics[SPI.ACOU] Engineering Sciences [physics]/Acoustics [physics.class-ph]BENDS[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]Science & Technology02 Physical SciencesCondensed Matter - Mesoscale and Nanoscale PhysicsPhysicsAcoustic waveEDGE STATES021001 nanoscience & nanotechnology[PHYS.MECA.ACOU]Physics [physics]/Mechanics [physics]/Acoustics [physics.class-ph]Pulse (physics)Cardinal pointSPINPhysical Sciences2-DIMENSIONAL PHOTONIC CRYSTALHIGH TRANSMISSIONUltrasonic sensor0210 nano-technologyPhysical Review Applied
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Thermal cloaking of complex objects with the neutral inclusion and the coordinate transformation methods

2019

We explore the cloaking of a complex shape by either the neutral inclusion or the transformation thermodynamics (TT) methods. Thin cloaks are built and the heat cloaking efficiency is investigated for both the steady-state and the transient regimes. We show that the neutral inclusion cloak is more efficient in both regimes, though it has the drawback that the thermal conductivity of the cloaked shape must be known. In practice, the neutral inclusion method is more flexible and easier to implement than the coordinate transformation method, especially for complex shapes.We explore the cloaking of a complex shape by either the neutral inclusion or the transformation thermodynamics (TT) methods…

010302 applied physicsPhysics[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]Coordinate systemCloakGeneral Physics and AstronomyCloaking02 engineering and technology021001 nanoscience & nanotechnology01 natural scienceslcsh:QC1-999[SPI.MAT]Engineering Sciences [physics]/MaterialsThermal conductivityClassical mechanicsTransformation (function)0103 physical sciencesThermalTransient (oscillation)Inclusion (mineral)[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics0210 nano-technologylcsh:Physics
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Acousto-optic cavity coupling in 2D phoxonic crystal with combined convex and concave holes

2021

International audience; A two-dimensional cross-like phoxonic crystal (PxC) model is proposed, which exhibits simultaneously large complete photonic crystal (PtC) and phononic crystal (PnC) bandgaps. The most salient trait of the structure is the wide range of geometrical parameters compatible with large complete bandgaps. After geometrical optimization, photonic and phononic bandgaps with gap-to-midgap ratios of 11.5% and 90.7% are obtained, respectively. These values are close to the best topology-optimized reported values but are obtained with simple shapes compatible with nanoscale fabrication technology. These characteristics make the convex–concave topology a promising candidate for P…

CouplingPhysics[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]PhotonCondensed matter physicsPhononbusiness.industryGeneral Physics and AstronomyPhysics::Optics02 engineering and technology021001 nanoscience & nanotechnology01 natural sciencesFinite element method[SPI.MAT]Engineering Sciences [physics]/MaterialsCrystalSuperposition principle0103 physical sciencesPhotonics[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics010306 general physics0210 nano-technologybusinessPhotonic crystal
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Low-frequency band gap in cross-like holey phononic crystal strip

2018

International audience; A silicon-based cross-like holey phononic crystal (PnC) strip is proposed for the control of elastic waves in the field of micro-electro-mechanical systems (MEMS). The goal is to obtain a broad bandgap at low frequencies with a lightweight structure. In this respect, the effects of varying the in-plane and the out-of-plane geometry parameters are discussed. After design, a gap-to-midgap ratio of 47% is obtained with an intermediate filling fraction of the solid material and a small thickness of the strip. The band gap can be moved to an extremely low frequency range while keeping the strip significantly smaller than previously reported PnC strips. The transmission pr…

Materials scienceAcoustics and UltrasonicsSiliconBand gapchemistry.chemical_element02 engineering and technologySTRIPS01 natural scienceslaw.invention[SPI.MAT]Engineering Sciences [physics]/MaterialsCrystalResonatorlaw0103 physical sciencesExtremely low frequency[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/MicroelectronicsElectronic band structure010302 applied physicsMicroelectromechanical systems[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]business.industry021001 nanoscience & nanotechnologyCondensed Matter PhysicsSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialschemistryOptoelectronics0210 nano-technologybusiness
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Ultra-Wide Band Gap in Two-Dimensional Phononic Crystal with Combined Convex and Concave Holes

2017

A phononic crystal with an ultra‐wide band gap is proposed, whose unit cell consists of a cross‐like concave hole in the center and four square convex holes at the corners. The dispersion relations, modal kinetic energy ratio, and eigenmodes at edges of the band gaps are investigated by using the finite element method. The influence of the geometrical parameters of the convex and concave holes on the band gaps is further analyzed. After optimization, an ultra‐wide band gap with gap‐to‐midgap ratio of 156.0% is achieved, with the filling fraction keeping a relative small value. Numerical results illustrate that the combination of convex and concave holes is a practicable direction for struct…

010302 applied physicsMaterials scienceCondensed matter physicsBand gapRegular polygonUltra-wideband02 engineering and technology021001 nanoscience & nanotechnologyCondensed Matter PhysicsKinetic energy01 natural sciencesSquare (algebra)Finite element methodCrystalDispersion relation0103 physical sciencesGeneral Materials Science0210 nano-technologyphysica status solidi (RRL) - Rapid Research Letters
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Reconfigurable waveguides defined by selective fluid filling in two-dimensional phononic metaplates

2022

Abstract We investigate two-dimensional phononic metaplates consisting of a periodic array of cups on a thin epoxy plate that is perforated with periodic cross holes. The cups are individually filled with water or remain empty, in view of creating reconfigurable phononic waveguides. Phononic band gaps exist for empty or filled epoxy cups, leading to waveguides defined with either positive or negative contrast. Straight and 90° bent waveguides are considered experimentally. Lamb waves are excited by a piezoelectric patch glued onto the metaplate and are imaged using a scanning laser vibrometer. Experimental results are compared to a three-dimensional finite element model of fluid–structure i…

CouplingMaterials scienceBand gapbusiness.industryMechanical EngineeringBent molecular geometryAerospace EngineeringAcoustic wavePiezoelectricityFinite element methodComputer Science ApplicationsLamb wavesOpticsControl and Systems EngineeringSignal ProcessingLaser scanning vibrometrybusinessCivil and Structural EngineeringMechanical Systems and Signal Processing
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Experimental observations of topologically guided water waves within non-hexagonal structures

2020

International audience; We investigate symmetry-protected topological water waves within a strategically engineered square lattice system. Thus far, symmetry protected topological modes in hexagonal systems have primarily been studied in electromagnetism and acoustics, i.e., dispersionless media. Herein, we show experimentally how crucial geometrical properties of square structures allow for topological transport that is ordinarily forbidden within conventional hexagonal structures. We perform numerical simulations that take into account the inherent dispersion within water waves and devise a topological insulator that supports symmetry-protected transport along the domain walls. Our measur…

Physics and Astronomy (miscellaneous)Structure (category theory)FOS: Physical sciences02 engineering and technology01 natural sciences09 EngineeringSquare (algebra)[SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph][SPI.MAT]Engineering Sciences [physics]/MaterialsElectromagnetism10 Technologycond-mat.mes-hallMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciences[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/MicroelectronicsDispersion (water waves)ComputingMilieux_MISCELLANEOUSApplied Physics010302 applied physicsPhysics[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph]02 Physical SciencesCondensed Matter - Mesoscale and Nanoscale PhysicsFluid Dynamics (physics.flu-dyn)Physics - Fluid Dynamics021001 nanoscience & nanotechnologySquare latticeComputational physicsphysics.flu-dynTopological insulatorDomain (ring theory)0210 nano-technologyEnergy (signal processing)
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Extraordinary nonlinear transmission modulation in a doubly resonant acousto-optical structure

2017

International audience; Acousto-optical modulators usually rely on coherent diffraction of light by a moving acoustic wave, leading to bulky devices with a long interaction length. We propose a subwavelength acousto-optical structure that instead relies on a double resonance to achieve strong modulation at near-infrared wavelengths. A periodic array of metal ridges on a piezoelectric substrate defines cavities that create a resonant dip in the optical transmission spectrum. The ridges simultaneously support large flexural vibrations when resonantly excited by a radio-frequency signal, effectively deforming the cavities and leading to strongly nonlinear acousto-optical modulation. The nano-o…

DiffractionMaterials sciencePhysics::Optics02 engineering and technology01 natural sciencesSignal[SPI.MAT]Engineering Sciences [physics]/MaterialsOptics0103 physical sciences[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics010306 general physics[SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph][PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]business.industryFano resonanceAcoustic wave021001 nanoscience & nanotechnologyAtomic and Molecular Physics and OpticsElectronic Optical and Magnetic MaterialsWavelengthSurface waveModulationOptoelectronicsPhotonics0210 nano-technologybusiness
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3034461.pdf

2017

Supplemental document

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3034461.pdf

2017

Supplemental document

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spectres.mp4

2017

The movie shows the temporal evolution of the optical transmission spectrum through a nanophotonic periodic structure that is being deformed as a function of time by an acoustic resonance at 500 MHz. The vibrating pillars are made of silver and the piezoelectric substrate is made of lithium niobate. The period of the structure is 640 nm.

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lfixe.mp4

2017

The movie shows the temporal evolution of the optical transmission through a nanophotonic periodic structure that is being deformed as a function of time by an acoustic resonance at 500 MHz. The optical wavelength is fixed. The vibrating pillars are made of silver and the piezoelectric substrate is made of lithium niobate. The period of the structure is 640 nm.

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spectres.mp4

2017

The movie shows the temporal evolution of the optical transmission spectrum through a nanophotonic periodic structure that is being deformed as a function of time by an acoustic resonance at 500 MHz. The vibrating pillars are made of silver and the piezoelectric substrate is made of lithium niobate. The period of the structure is 640 nm.

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lfixe.mp4

2017

The movie shows the temporal evolution of the optical transmission through a nanophotonic periodic structure that is being deformed as a function of time by an acoustic resonance at 500 MHz. The optical wavelength is fixed. The vibrating pillars are made of silver and the piezoelectric substrate is made of lithium niobate. The period of the structure is 640 nm.

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