Jean-Michel Gérard focuses on Quantum dot, Condensed matter physics, Optoelectronics, Photoluminescence and Spontaneous emission. Jean-Michel Gérard has included themes like Doping, Photon, Cavity quantum electrodynamics, Electron and Quantum dot laser in his Quantum dot study. He combines subjects such as Polaron, Quantum and Self assembled with his study of Condensed matter physics.
His Optoelectronics study frequently involves adjacent topics like Scale. His Photoluminescence study combines topics in areas such as Molecular beam epitaxy, Resonance, Exciton, Quantum well and Etching. His work deals with themes such as Photonics and Quantum optics, which intersect with Spontaneous emission.
Optoelectronics, Quantum dot, Condensed matter physics, Optics and Photoluminescence are his primary areas of study. His Optoelectronics research is multidisciplinary, incorporating perspectives in Spontaneous emission and Photon. He has researched Photon in several fields, including Cavity quantum electrodynamics, Optical microcavity and Atomic physics.
The study incorporates disciplines such as Quantum optics, Gallium arsenide, Spectroscopy, Exciton and Quantum dot laser in addition to Quantum dot. His Condensed matter physics research focuses on Quantum well and how it relates to Heterojunction and Monolayer. As a part of the same scientific family, Jean-Michel Gérard mostly works in the field of Photoluminescence, focusing on Molecular beam epitaxy and, on occasion, Thin film.
Jean-Michel Gérard mainly focuses on Optoelectronics, Optics, Quantum dot, Photonics and Photon. His Optoelectronics research is multidisciplinary, incorporating elements of Ultrashort pulse and Quantum optics. The concepts of his Quantum dot study are interwoven with issues in Quantum information, Quantum, Exciton and Quantum dot laser.
His work carried out in the field of Photonics brings together such families of science as Wafer, Gaussian beam, Quantum technology, Single-photon source and Photoluminescence. His Photon research incorporates themes from Waveguide, Spontaneous emission, Stimulated emission, Atom and Atomic physics. His work in the fields of Purcell effect overlaps with other areas such as Mode volume.
His primary scientific interests are in Optoelectronics, Quantum dot, Photon, Photonics and Optics. His Optoelectronics research incorporates elements of Ultrashort pulse and Quantum optics. His research integrates issues of Exciton, Semiconductor, Quantum information, Photoluminescence and Antenna in his study of Quantum dot.
His Quantum information study combines topics from a wide range of disciplines, such as Scanning probe microscopy and Quantum dot laser. His research on Photon also deals with topics like
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Photoluminescence of single InAs quantum dots obtained by self-organized growth on GaAs.
J. Y. Marzin;J. M. Gérard;A. Izraël;D. Barrier.
Physical Review Letters (1994)
Enhanced Spontaneous Emission by Quantum Boxes in a Monolithic Optical Microcavity
J. M. Gérard;B. Sermage;B. Gayral;B. Legrand.
Physical Review Letters (1998)
A highly efficient single-photon source based on a quantum dot in a photonic nanowire
Julien Claudon;Joël Bleuse;Nitin Singh Malik;Maela Bazin.
Nature Photonics (2010)
Exciton-photon strong-coupling regime for a single quantum dot embedded in a microcavity.
E. Peter;P. Senellart;D. Martrou;A. Lemaître.
Physical Review Letters (2005)
Single-mode solid-state single photon source based on isolated quantum dots in pillar microcavities
E. Moreau;I. Robert;J. M. Gérard;I. Abram.
Applied Physics Letters (2001)
Strong-coupling regime for quantum boxes in pillar microcavities: Theory
Lucio Claudio Andreani;Giovanna Panzarini;Jean-Michel Gérard.
Physical Review B (1999)
Spin Relaxation Quenching in Semiconductor Quantum Dots
M. Paillard;X. Marie;P. Renucci;T. Amand.
Physical Review Letters (2001)
Strong Purcell effect for InAs quantum boxes in three-dimensional solid-state microcavities
J.-M. Gerard;B. Gayral.
Journal of Lightwave Technology (1999)
Strong Electron-Phonon Coupling Regime in Quantum Dots: Evidence for Everlasting Resonant Polarons
S. Hameau;Y. Guldner;O. Verzelen;R. Ferreira.
Physical Review Letters (1999)
Quantum Cascade of Photons in Semiconductor Quantum Dots
E. Moreau;I. Robert;L. Manin;V. Thierry-Mieg.
Physical Review Letters (2001)
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