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In the combustion field, applications used to deal with [http://www.coria-cfd.fr/index.php/User:Dangelo combustive flows] & thermoelectric conversion at the small scale, flame/wall interaction, expanding wrinkled flames, flame-balls & ignition kernels analysis, flame/acoustics interaction, percolation modeling for front propagation, stratified combustion modeling in engines. | In the combustion field, applications used to deal with [http://www.coria-cfd.fr/index.php/User:Dangelo combustive flows] & thermoelectric conversion at the small scale, flame/wall interaction, expanding wrinkled flames, flame-balls & ignition kernels analysis, flame/acoustics interaction, percolation modeling for front propagation, stratified combustion modeling in engines. | ||
| − | More recent applications concern buoyant thermal destabilization in wet granular media and non-Newtonian flows (with [http://inphyni.cnrs.fr/en/research/nonlinear-physics-complex-fluids-and-biophysics/concentrated-suspensions-rheology Institut de Physique de Nice]), biological dynamic expanding networks (see the | + | More recent applications concern buoyant thermal destabilization in wet granular media and non-Newtonian flows (with [http://inphyni.cnrs.fr/en/research/nonlinear-physics-complex-fluids-and-biophysics/concentrated-suspensions-rheology Institut de Physique de Nice]), biological dynamic expanding networks (see the DREAMS/Nematic project below), thermodynamics of metabolic energy conversion under muscle load, ecological economics (with AFD), and also very recently thermoplasmonics at the nanoscale with the [http://www-sop.inria.fr/atlantis/ Inria Atlantis Team]. Collaborations with [https://www.fresnel.fr/spip/spip.php?article2327 Guillaume Baffou] at Institut Fresnel in Marseille and [https://www.polymtl.ca/phys/michel-meunier Michel Meunier] at Polytechnique Montréal are in progress. |
<span style="font-size: 110%; border: "><span style="color:#FF0000"> <strong>At LIED and LJAD Labs </strong></span></span>, recent applications and collaborations concern: | <span style="font-size: 110%; border: "><span style="color:#FF0000"> <strong>At LIED and LJAD Labs </strong></span></span>, recent applications and collaborations concern: | ||
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* Buoyant destabilization in [http://www.dyco.fr/index.php/Buoyant_destabilization_in_wet_granular_media_%26_non-Newtonian_flows wet granular media & non-Newtonian flows] with DYCO and [http://inphyni.cnrs.fr/en/research/nonlinear-physics-complex-fluids-and-biophysics/concentrated-suspensions-rheology InPhiNi] ; | * Buoyant destabilization in [http://www.dyco.fr/index.php/Buoyant_destabilization_in_wet_granular_media_%26_non-Newtonian_flows wet granular media & non-Newtonian flows] with DYCO and [http://inphyni.cnrs.fr/en/research/nonlinear-physics-complex-fluids-and-biophysics/concentrated-suspensions-rheology InPhiNi] ; | ||
* Eyeglass-framed thermoelectric micro-converter analysis & design (with [https://www.pcuv.es/en/empresas-instaladas/Biotecnolog-a/BIOPOLIS BioPolis]/[https://www.pcuv.es/en/empresas-instaladas//DARWIN-BIOPROSPECTING-EXCELLENCE--S-L Darwin], Valencia, Spain); (''stand-by'') | * Eyeglass-framed thermoelectric micro-converter analysis & design (with [https://www.pcuv.es/en/empresas-instaladas/Biotecnolog-a/BIOPOLIS BioPolis]/[https://www.pcuv.es/en/empresas-instaladas//DARWIN-BIOPROSPECTING-EXCELLENCE--S-L Darwin], Valencia, Spain); (''stand-by'') | ||
| − | * <span style="font-size: 100%; border: "><span style="color:#FF0000"> Analysis of Dynamical Expanding Networks: modeling multi-scale spatial exploration, spreading & morphogenesis,</span></span> especially in the biologic context. Our archetypal example & investigation topic is the constrained hyphal growth of the filamentous fungus '' | + | * <span style="font-size: 100%; border: "><span style="color:#FF0000"> Analysis of Dynamical Expanding Networks: modeling multi-scale spatial exploration, spreading & morphogenesis,</span></span> especially in the biologic context. Our archetypal example & investigation topic is the constrained hyphal growth of the filamentous fungus ''Podospora anserina'' (the [https://workshopdena17.sciencesconf.org DENA]/[http://www.dyco.fr/index.php/DREAMS DREAMS project]. The involved partners are [http://math.unice.fr/~rcatelli LJAD], [http://www-sop.inria.fr/members/Laurent.Monasse/ Inria COFFEE], the [http://www.lied-pieri.univ-paris-diderot.fr/?emd_person=brouillon-auto-15 B2C group] and Physics Group at LIED, the [https://www.math.u-psud.fr/~olivier/ LMO] at Orsay, the [http://www.cmap.polytechnique.fr/~veber/ CMAP] at Ecole Polytechnique, and also [http://users.dma.unipi.it/flandoli/ SNS Pisa]. |
* Nano-thermoplasmonics modeling & simulation: coupling (hyperbolic) heat transfer equations and Maxwell equations at the nanoscale; further coupling with the dynamics of possibly reactive flows). Collaboration with [https://www-sop.inria.fr/atlantis/ Inria ATLANTIS Team] <span style="font-size: 100%; border: "><span style="color:#FF0000"> (in progress !) </span></span> | * Nano-thermoplasmonics modeling & simulation: coupling (hyperbolic) heat transfer equations and Maxwell equations at the nanoscale; further coupling with the dynamics of possibly reactive flows). Collaboration with [https://www-sop.inria.fr/atlantis/ Inria ATLANTIS Team] <span style="font-size: 100%; border: "><span style="color:#FF0000"> (in progress !) </span></span> | ||
Revision as of 21:19, 10 September 2022
Contents
Since September 2016, I am Full Professor of Applied Mathematics at Université Côte d'Azur (formerly University of Nice-Sophia Antipolis) and Researcher at Laboratoire de Mathématiques & Interactions J.A. Dieudonné CNRS UMR 7351, in the Fluid Dynamics & Scientific Computing Group.
Since September 2019, I am Head of the J.A. Dieudonné Lab (~ 240 people).
From 2005 to 2016, I was Professor in the Energy & Propulsion Department, French Institute for Applied Sciences (INSA/CORIA), Rouen, France, and Researcher at CORIA Lab.
Research Interests
My main research interests deal with mathematical modeling, asymptotic analysis, numerical methods and scientific computing, first in fluid mechanics and combustion, more recently in the fields of fungal biology, nanothermoplasmonics and suspension flows.
In the combustion field, applications used to deal with combustive flows & thermoelectric conversion at the small scale, flame/wall interaction, expanding wrinkled flames, flame-balls & ignition kernels analysis, flame/acoustics interaction, percolation modeling for front propagation, stratified combustion modeling in engines.
More recent applications concern buoyant thermal destabilization in wet granular media and non-Newtonian flows (with Institut de Physique de Nice), biological dynamic expanding networks (see the DREAMS/Nematic project below), thermodynamics of metabolic energy conversion under muscle load, ecological economics (with AFD), and also very recently thermoplasmonics at the nanoscale with the Inria Atlantis Team. Collaborations with Guillaume Baffou at Institut Fresnel in Marseille and Michel Meunier at Polytechnique Montréal are in progress.
At LIED and LJAD Labs , recent applications and collaborations concern:
- Ecological Economics, with AFD and Energy & Prosperity Chair ;
- Thermodynamics of metabolic energy conversion under muscle load and in particular the cost of oxygen question, with DYCO Team and Skolkovo Institute of Science and Technology, in Moscow ;
- Buoyant destabilization in wet granular media & non-Newtonian flows with DYCO and InPhiNi ;
- Eyeglass-framed thermoelectric micro-converter analysis & design (with BioPolis/Darwin, Valencia, Spain); (stand-by)
- Analysis of Dynamical Expanding Networks: modeling multi-scale spatial exploration, spreading & morphogenesis, especially in the biologic context. Our archetypal example & investigation topic is the constrained hyphal growth of the filamentous fungus Podospora anserina (the DENA/DREAMS project. The involved partners are LJAD, Inria COFFEE, the B2C group and Physics Group at LIED, the LMO at Orsay, the CMAP at Ecole Polytechnique, and also SNS Pisa.
- Nano-thermoplasmonics modeling & simulation: coupling (hyperbolic) heat transfer equations and Maxwell equations at the nanoscale; further coupling with the dynamics of possibly reactive flows). Collaboration with Inria ATLANTIS Team (in progress !)
Lab Address
Laboratoire Mathématiques & Interactions J.A. Dieudonné
Université Côte d'Azur CNRS UMR 7351
Parc Valrose 06108 NICE CEDEX, France
ydangelo@unice.fr, yves.dangelo@univ-cotedazur.fr
Also
INRIA Atlantis Team
2004 Route des Lucioles 06902 Valbonne, France
Solvers
My team and I developed/still developing the following solvers:
- DYCO, for simulating coupled potentials stock/flow approach network dynamics and application to thermo-electricity, biology, economics.
- HALLEGRO for solving fully compressible subsonic reactive Navier-Stokes equations (HPC using MPI).
- FLAMEX for solving asymptotics-based evolution equations, in particular propagating fronts through turbulent 2D and 3D flows (spectral/ETDRK methods for Sivashinsky-type non-linear non-local equations).
We now also make use of adapted versions of the OpenFOAM® software.
International & Industrial Collaborations
International Collaborations
Skolkovo Institute, Moscow; Politecnico Milano, Italy; CUED Cambridge University Engineering Department, UK ; Chair of Fluid Mechanics, TU Berlin, Germany; LTH, Lund University of Technology, Sweden: Dept. of Aircraft Technology, Institute of Nanoscience and Nanotechnology, Greece; University of Valencia, Spain;
Queensland University of Technology, Australia; Institut Fresnel, Marseille; Ecole Polytechnique de Montréal, Canada.
Industrial Collaborations
Renault, IFPEN, ONERA, HBOB Grenoble, ST MicroElectronics Tours, BioPolis Spain.
External Links
and also the
- Stratified and MesoScale combustion applications at CORIA-CFD.