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ELyTMaX est un Laboratoire de Recherche International (IRL) lancé par le CNRS (France), l'Université de Lyon (France) et l'Université du Tohoku (Japon). ELyTMaX est situé à l'Université du Tohoku à Sendai et à l'Université de Lyon. Le laboratoire regroupe environ une vingtaine de personnes (à la fois en France et au Japon) incluant des Professeurs, Maîtres de Conférences, postDoc, doctorants et Master en double diplôme, et du personal administratif.
Dernières Publications
Données de contact
Coordonnées :
Room #503 Material Solutions Center (MaSC)
Engineering sciences Lyon-Tohoku joint lab for Materials under extreme conditions (ELyTMaX), Tohoku University
2-1-1 Katahira, Aoba-ku, Sendai 980-0813 Japan
Site Web de ELyTMaX
Room #503 Material Solutions Center (MaSC)
Engineering sciences Lyon-Tohoku joint lab for Materials under extreme conditions (ELyTMaX), Tohoku University
2-1-1 Katahira, Aoba-ku, Sendai 980-0813 Japan
Site Web de ELyTMaX
Documents en texte intégral
122
Recherche
Mots clés
Ericsson cycle
Condensation capillaire
Polyurethane
Strain induced crystallization
Polymer coating
Dealloying
Internal stress
Magnetization rotation
Bayesian optimization
Fractional derivative
Polymers
Anelastic relaxation
Beta relaxation
Contact area
Brake squeal
Aimantation
Analytical criterion
Arterial stiffness
Computational morphogenesis
Permeability
Energy conversion
Cole-Cole model
Non-destructive testing
Capacitive sensor
Cold spray
Ferroelectric
Anomalous diffusion
Water uptake
Brownian motion
Active regeneration
Chemical microstructure
Carbon nanotubes
Capillary condensation
Architected materials
Butadiene
Gallium nitride GaN
Polymer
Ionic liquid
Predictive maintenance
Abradant concentration
Adhesion
Multiscale model
Actuators
Magnetic losses
Eddy current testing
Rubber elasticity
Fractional derivatives
Cell membranes
Magnetic incremental permeability
Magnetic hysteresis
Frequency dependence
Bruit de Barkhausen
Fluid dynamics
Magnetic laminations stack
Conducting polymers
Elastocaloric
Cell structure
Corrosion resistance
Bending
Thermal gradient
Magnetization mechanism
Absorption de l’eau
Local defect
Compressive stress
BARKHAUSEN NOISE
Natural rubber
Bruit Barkhausen
Ceramic particles
Magnetic non-destructive testing
Simulation
Energy harvesting
Amorphous polymer
Cellulose nanofiber
Carbon steel
Barkhausen noise
Magnetostriction
Jiles-Atherton model
CARBON-STEEL
Finsler geometry
Additive manufacturing
Activation energy
Agglomerated powder
Computer simulation
Aging
Magnetic sensor
Infrared imaging
Barkhausen
Adhesive bonding
Compressive residual stress
Caloric materials
Solid-state cooling
Alternating losses
Capteur capacitif
Composite
Ceramic powder
Contraintes mécaniques
Magnetic Barkhausen noise
Epoxy coating
Energy density
Hysteresis