Laboratoire Charles Coulomb UMR 5221 CNRS/UM2 (L2C)

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Accueil > La Recherche > Axes & Equipes > Physique de l’Exciton, du Photon & du Spin > Théorie du Rayonnement-Matière et Phénomènes Quantiques

Théorie du Rayonnement-Matière et Phénomènes Quantiques


The "Theory of light-matter and quantum phenomena" (RMPQ) group has been founded to promote theoretical studies on elementary and collective quantum effects, at the crossroads between light-matter physics, condensed matter, and ultra-cold quantum gases.

RMPQ is the theory group of the "PEPS division".

Group activities are developed in close collaboration with several national and international experimental groups, and are motivated by both fundamental and applicative challenges in quantum physics.

Main group research activities, conducted by means of analytical and advanced numerical tools in theoretical physics, are :

  • non-equilibrium dynamics in quantum physics (Casimir-Lifshiz interaction, heat transfer, fluctuations-dissipation theorems, entanglement, light-harvesting complexes, quantum thermal machines)


  • light and energy transport properties in periodic or disordered quantum complex systems (ultra cold quantum gases, quantum dots, photonics crystals, artificial atomic crystals, graphene)


  • few and many-body quantum physics (Bose-Einstein condensation, collective oscillations, solitons, and quantum vortices in Bose and Fermi atomic gases, polaritons in semiconductors)


  • plasmonics and nanophotonics (graphene, gratings, numerical electromagnetism)


For more informations on the group research click here.


From left to right : David Cassagne, Bruno Leggio, Hamis Gargoubi, Riccardo Messina, Brahim Guizal, Mauro Antezza, Pierre Doyeux

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Dernières publications

+ Strong Thermal and Electrostatic Manipulation of the Casimir Force in Graphene Multilayers doi link

Auteur(s): Abbas C., Guizal B., Antezza M.(Corresp.)

(Article) Publié: Physical Review Letters, vol. 118 p.126101 (2017)

 
+ Radiative heat transfer between metallic gratings using Fourier modal method with adaptive spatial resolution doi link

Auteur(s): Messina R., Noto A., Guizal B., Antezza M.

(Article) Publié: Physical Review B, vol. 95 p.125404 (2017)

 
+ Many body heat radiation and heat transfer in the presence of a non-absorbing background medium doi link

Auteur(s): Boris Muller, Roberta Incardone, Antezza M., Thorsten Emig, Matthias Kruger

(Article) Publié: Physical Review B, vol. 95 p.085413 (2017)

 


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