François Gallaire

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Local: MED 2 2926
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Biographie

Né le 26 février 1975, François Gallaire obtient, en 1998, le diplôme dingénieur de lEcole Polytechnique à Paris et, en 1999, un master en « Physique des liquides » à lUniversité Pierre et Marie Curie, toujours à Paris. Il rejoint ensuite le Laboratoire dhydrodynamique (LadHyX) à lEcole polytechnique où il soutient, en 2003, une thèse sur le thème des instabilités des jets tournants et sur le contrôle de léclatement tourbillonnaire sous la direction de Jean-Marrc Chomaz. En 2003, il est nommé chargé de recherche au CNRS au Laboratoire J.A. Dieudonné de lUniversité de Nice Sophia-Antipolis.En 2009, il rejoint l'EPFL pour y fonder le laboratoire des mécanique des fluides et instabilités (LFMI).

Ses recherches se concentrent sur létude des propriétés fondamentales de stabilité des écoulements de fluides et sont guidées par les applications réelles, en particulier le contrôle des écoulements. Récemment, il a réalisé dimportantes contributions dans les domaines de la micro-fluidique (lanalyse de la manipulation par laser dune goutte dans un micro-canal) et la dynamique des bio-fluides (le descriptif mécanique de lanévrisme de laorte abdominale).

Parcours professionnel

Chargé de recherche CNRS

Laboratoire Dieudonné, Université de Nice-Sophia Antipolis

09/2003-08/2009

Professeur assistant

LFMI

EPFL

09/2009-

Publications

Autres publications

PUBLICATIONS REPRESENTATIVES

Review papers

1. F. Gallaire and P.-T. Brun, “Fluid dynamic instabilities: theory and application to pattern forming in complex media”, Phil. Trans. Roy. Soc. A, 375, 2017,
2. C. Baroud, F. Gallaire and R. Dangla, “Flow physics of droplet microfluidics”, Lab on the Chip, 10, 2972-2978, 2010,

Drops

Drop deformation and transport

1. S. Y. Reigh, L. Zhu , F. Gallaire and E. Lauga, “Swimming with a cage: low-Reynolds-number locomotion inside a droplet”, Soft Matter, 13(17), 3161–3173, 2017,
2. G. Gallino, L. Zhu and F. Gallaire, “The stability of a rising droplet: an inertialess non-modal growth mechanism”, J. Fluid Mech., 786, 2015,
3. F. Thommen, F. Gallaire, D. Psaltis and T.Wolfensberger, “Modified McCannel Iridoplasty Simulating Basal Iridectomy for Silicone Oil Tamponade in Aphakia and Partial Aniridia”, Klinsiche Monatsblatter für Augenheilkunde, 231, 4, 418-420, 2014,

Squeezed drops

1. G. Amselem, P. T. Brun, F. Gallaire and C. N. Baroud, “Breaking Anchored Droplets in a Microfluidic Hele-Shaw Cell”, Phys. Rev. Applied, 3, 2015,
2. M. Nagel and F. Gallaire, “Boundary elements method for microfluidic two-phase flows in shallow channels”, Computers & Fluids, 107, 2015,
3. F. Gallaire, P. Meliga, P. Laure and C. Baroud, “Marangoni induced force on a drop in a Hele Shaw cell”, Phys. Fluids, 26(6), 2014,
4. M. Nagel, P.-T. Brun and F. Gallaire, “A numerical study of droplet trapping in microfluidic devices”, Phys. Fluids, 26(3), 2014,
5. M. Nagel and F. Gallaire, “A new prediction of wavelength selection in radial viscous fingering involving normal and tangential stresses”, Phys. Fluids, 25(12), 2013,
6. P.-T. Brun, M. Nagel and F. Gallaire, “Generic path for droplet relaxation in microfluidic channels”, Phys. Rev. E, 88(4), 2013,
7. Microchannel deformations due to solvent-induced PDMS swelling, R. Dangla, C. Baroud and F. Gallaire, Lab on the Chip, 10, 2972-2978 (2010),
8. Laser-induced force on a microfluidic drop: Origin and magnitude, E. Verneuil, M.-L. Cordero, F. Gallaire & C. N. Baroud, Langmuir 25, 5127-5134, (2009),
9. Time resolved temperature rise in a thin liquid film due to laser absorption, M.-L. Cordero, E. Verneuil, F. Gallaire & C. Baroud, Phys. Rev. E. 79, 011201, (2009),

Drop generation

1. M. Moire, Y. Peysson, B. Herzhaft, N. Pannacci, F. Gallaire, L. Augello, C. Dalmazzone and A. Colin, “Ultralow Interfacial Tension Measurement through Jetting/Dripping Transition”, Langmuir, 33(10), 2531–2540, 2017,
2. P. Delrot, M. Modestino, F. Gallaire, D. Psaltis and C. Moser, “Inkjet Printing of Viscous Monodisperse Microdroplets by Laser-Induced Flow Focusing”, Phys. Rev. Applied, 6(2), 2016,
3. Quantitative analysis of the dripping and jetting regimes in co-flowing capillary jets, M.-L. Cordero, F. Gallaire & C. N. Baroud, Phys. Fluids, 23(9), (2011),

Sloshing dynamics

1. F. Viola, P.-T. Brun, B. Dollet and F. Gallaire, Capillary hysteresis in sloshing dynamics: a weakly nonlinear analysis, J. Fluid Mech., 837, 188-818, 2018,
2. F. Viola, F. Gallaire and B. Dollet, Sloshing in a Hele-Shaw cell: experiments and theory, J. Fluid Mech., 831, R1, 2017,
3. F. Viola, P.-T. Brun, B. Dollet and F. Gallaire, “Foam on troubled water: Capillary induced finite-time arrest of sloshing waves”, Phys. Fluids, 26(9), 2016,

Fluid-solid interactions

1. L. Zhu and F. Gallaire, “Bifurcation Dynamics of a Particle-Encapsulating Droplet in Shear Flow”, Phys. Rev. Lett., 119(6), 2017,
2. F. Viola and F. Gallaire, “The viscous torsional pendulum”, J. Fluids Struct., 72, 25–37, 2017,
3. A. Fani and F. Gallaire, “The motion of a 2D pendulum in a channel subjected to an incoming flow”, J. Fluid Mech., 764, 2015,
4. Extracting energy from a low Reynolds-number-flow using vortex-induced vibrations and feedback control, P. Meliga, J.-M. Chomaz and F. Gallaire, J. Fluids Struct., 27, 861-874,
5. A fluid mechanical view on Abdominal Aortic Aneurysms, V. Duclaux, C. Clanet and F. Gallaire, J. Fluid Mech., 664, 5-32, (2010),

Thin films and coating flows

1. G. Balestra, N. Kofman, P.-T. Brun, B. Scheid and F. Gallaire, Three-dimensional Rayleigh-Taylor instability under a unidirectional curved substrate, J. Fluid Mech., 837, 19-47, 2018.
2. M. Rietz, B. Scheid, F. Gallaire, N. Kofman and W. Rohlfs, Dynamics of falling films on the outside of a vertical rotating cylinder: waves, rivulets and dripping transitions, J. Fluid Mech., 832, 189-211, 2017,
3. G. Balestra, P.-T. Brun and F. Gallaire, “Rayleigh-Taylor instability under curved substrates: An optimal transient growth analysis”, Phys. Rev. Fluids, 1(8), 2016,
6. Lee, P. -T. Brun, J. Marthelot, G. Balestra, F. Gallaire and P. M. Reis, “Fabrication of slender elastic shells by the coating of curved surfaces”, Nature Communications, 7, 2016,
7. P.-T. Brun, A. Damiano, P. Rieu, G. Balestra and F. Gallaire, “Rayleigh-Taylor instability under an inclined plane”, Phys. Fluids, 27, 2015,

Instability theory and flow control

1. Y. Anzai, K. Fukagata, P. Meliga, E. Boujo and F. Gallaire, “Numerical simulation and sensitivity analysis of a low-Reynolds-number flow around a square cylinder controlled using plasma actuators”, Phys. Rev. Fluids, 2(4), 2017,
2. V. Mantic-Lugo and F. Gallaire, “Saturation of the response to stochastic forcing in two-dimensional backwardfacing step flow: A self-consistent approximation”, Phys. Rev. Fluids, 1(8), 2016,
3. F. Gallaire, E. Boujo, V. Mantic-Lugo, C. Arratia, B. Thiria and P. Meliga, “Pushing amplitude equations far from threshold: application to the supercritical Hopf bifurcation in the cylinder wake”, Fluid Dyn. Res.,
4. P. Meliga, E. Boujo and F. Gallaire, “A self-consistent formulation for the sensitivity analysis of finiteamplitude vortex shedding in the cylinder wake”, J. Fluid Mech., 800, 2016,
5. V. Mantic-Lugo and F. Gallaire, “Self-consistent model for the saturation mechanism of the response to harmonic forcing in the backward-facing step flow”, J. Fluid Mech., 793, 2016,
6. E. Boujo, A. Fani and F. Gallaire, “Second-order sensitivity of parallel shear flows and optimal spanwiseperiodic flow modifications”, J. Fluid Mech., 782, 2015,
7. V. Mantic-Lugo, C. Arratia and F. Gallaire, “A self-consistent model for the saturation dynamics of the vortex shedding around the mean flow in the unstable cylinder wake”, Phys. Fluids, 27, 2015,
8. F. Gallaire, “The effect of rounding corners or cutting edges on the absolute/convective instability properties of mixing layers”, Eur. J. Mech. B-Fluids, 49, 2015,
9. E. Boujo and F. Gallaire, “Sensitivity and open-loop control of stochastic response in a noise amplifier flow: the backward-facing step”, J. Fluid Mech., 762, 2015,
10. P. Meliga, E. Boujo, G. Pujals and F. Gallaire, “Sensitivity of aerodynamic forces in laminar and turbulent flow past a square cylinder”, Phys. Fluids, 26, 2014,
11. E Boujo and F. Gallaire, “Manipulating flow separation: sensitivity of stagnation points, separatrix angles and recirculation area to steady actuation”, Proc. Roy. Soc. A, 470, 2170, 2014,
12. V. Mantic-Lugo, C. Arratia and F. Gallaire, “Self-consistent mean flow description of the nonlinear saturation of the vortex shedding in the cylinder wake”, Phys. Rev. Lett., 113, 8, 084501, 2014,
13. E. Boujo, F. Gallaire and U. Ehrenstein, “Open-loop control of a separated boundary layer”, C. R. A. S., 342(6-7), 403-309, 2014,
14. E. Boujo and F. Gallaire, “Controlled reattachment in separated flows: a variational approach to recirculation length reduction”, J. Fluid Mech., 742, 618-635, 2014,
15. E Boujo, U. Ehrenstein and F. Gallaire, “Open-loop control of noise amplification in a separated boundary layer flow”, Phys. Fluids, 25(12), 2013,
16. Control of a separated boundary layer : Reduced order modeling using global modes revisited, U. Ehrenstein, P.-Y. Passaggia and F. Gallaire, , Theor. Comp. Fluid Dyn., 25, 195-207 (2011),

Vortex breakdown and swirling jet instabilities

1. F. Viola, E. Pezzica, G. V. Iungo, F. Gallaire and S. Camarri, “Flow control of weakly non-parallel flows: application to trailing vortices”, J. Fluid Mech., 822, 342–363, 2017,
2. S. Pasche, F. Avellan and F. Gallaire, “Part Load Vortex Rope as a Global Unstable Mode”, J. Fluids Eng., Trans. ASME, 139, 2017,
3. R. Ashton, F. Viola, S. Camarri, F. Gallaire and G. V. Iungo, “Hub vortex instability within wind turbine wakes: Effects of wind turbulence, loading conditions, and blade aerodynamics”, Phys. Rev. Fluids, 1(7), 2016,
4. J. T. Ault, A. Fabi, K. K. Chen, S. Shin, F. Gallaire and H. Stone, “Vortex-Breakdown-Induced Particle Capture in Branching Junctions”, Phys. Rev. Lett., 117(8), 2016,
5. T. Luginsland, F. Gallaire and L. Kleiser, “Impact of rotating and fixed nozzles on vortex breakdown in compressible swirling jet flows”, Eur. J. Mech. B-Fluids, 57, 2016,
6. F. Viola, C. Arratia and F. Gallaire, “Mode selection in trailing vortices: harmonic response of the nonparallel Batchelor vortex”, J. Fluid Mech., 790, 2016,
7. S. Pasche, F. Gallaire, M. Dreyer and M. Fahrat, “Obstacle-induced spiral vortex breakdown”, Expt. Fluids, 55, 8, 2014,
8. F. Viola, G. V. Iungo, S. Camarri, F. Porte-Agel and F. Gallaire, “Prediction of the hub vortex instability in a wind turbine wake: stability analysis with eddy-viscosity models calibrated on wind tunnel data”, J. Fluid Mech., 750, R1, 2014,
9. G. V. Iungo, F. Viola, S. Camarri, F. Porte-Agel and F. Gallaire, “Linear stability analysis of wind turbine wakes performed on wind tunnel measurements”, J. Fluid Mech., 737, 499-526, 2013,
10. P. Billant and F. Gallaire, “A unified criterion for the centrifugal instabilities of vortices and swirling jets”, J. Fluid Mech., 734, 5-35, 2013,
11. P. Meliga, F. Gallaire and J.-M. Chomaz “A weakly nonlinear mechanism for mode selection in swirling jets”, J. Fluid Mech., 699, 216-262, 2012,
12. Control of axisymmetric vortex breakdown in a contracting pipe: nonlinear steady states and asymptotic models, P. Meliga and F. Gallaire, Phys. Fluids, 23(8), (2011),

Effect of confinement on the instabilities of wakes and jets

1. S. Mowlavi, C. Arratia and F. Gallaire, “Spatio-temporal stability of the Karman vortex street and the effect of confinement”, J. Fluid Mech., 795, 2016,
2. L. Biancofiore, F. Gallaire, P. Laure and E. Hachem, “Direct numerical simulations of two-phase immiscible wakes”, Fluid Dyn. Res., 46, 4, 2014,
3. Influence of confinement on spatially developing turbulent wakes, L. Biancofiore, F. Gallaire and R. Pasquetti, Computers and Fluids, 58, 27-44 (2012)
4. Influence of confinement on spatially developing wakes, L. Biancofiore, F. Gallaire and R. Pasquetti, J. Fluid Mech., 688, 297-320 (2011)
5. The influence of shear layer thickness on the stability of confined two-dimensional wakes, L. Biancofiore and F. Gallaire, Phys. Fluids, 23(3), 2011
6. Influence of confinement on the temporal instability of jets and wakes, L. Biancofiore and F. Gallaire, Phys. Fluids, 22, 014106, (2010)

Wave coupling

1. L. Biancofiore, F. Gallaire and E. Heifetz, “Interaction between counterpropagating Rossby waves and capillary waves in planar shear flows”, Phys. Fluids, 27, 2015,
2. L. Biancofiore, E. Heifetz, J. Hoepffner and F. Gallaire, Understanding the destabilizing role for surface tension in planar shear flows in terms of wave interaction, Phys. Rev. Fluids, 2(10), 103901, 2017,

Recherche

voir le site http://lfmi.epfl.ch/

Enseignement & Phd

Enseignement

Mechanical Engineering

Programmes doctoraux

Doctorants

Bongarzone Alessandro, De Sepibus Cyprien Alexandre, Djambov Simeon Vladimirov, Ducimetière Yves-Marie François, Eghbali Shahab, Molefe Lebohang Calachan, Salamon Timothée Daniel, Wittkowski Kevin,

A dirigé les thèses EPFL de

Augello Laura , Balestra Gioele Mariano Nicolò , Boujo Edouard , Gallino Giacomo , Heidari Mahbod , Ledda Pier Giuseppe , Mantic Lugo Vladislav , Nagel Mathias , Papagiannopoulos Alexis , Pasche Simon , Shukla Isha , Viola Francesco ,

Cours

Méthode des éléments finis

L'étudiant acquiert une initiation théorique à la méthode des éléments finis qui constitue la technique la plus courante pour la résolution de problèmes elliptiques en mécanique. Il apprend à appliquer cette méthode à des cas simples et à l'exploiter pour résoudre les problèmes de la pratique.

Hydrodynamics

Les équations de Navier-Stokes sont adimensionnées, permettant la dérivation d'une cascade de modèles (Stokes, Lubrification, Euler, Potentiel) en fonction du nombre de Reynolds. La théorie de la couche limite permet alors l'identification des différentes composantes de la traînée hydrodynamique.

Two-phase flows and heat transfer

Ce cours couvre la théorie et l'application des écoulements diphasiques. Les transfert thermiques avec changement de phase, condensation et évaporation, sont étudiés. D'autres sujets avancés (écoulement diphasiques en micro-canaux ou en tubes micro-ailetés et influence de l'huile) sont aussi abordés

Instability

Ce cours traite des mécanismes physiques qui sont à l'origine de la transition entre un écoulement laminaire et turbulent en utilisant la théorie des instabilités hydrodynamiques.

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