The scientist’s investigation covers issues in Molecular physics, Nanoparticle, Atomic physics, Optics and Surface plasmon resonance. His work deals with themes such as Raman scattering, Raman spectroscopy, Cobalt, Excitation and Nuclear magnetic resonance, which intersect with Molecular physics. His Nanoparticle research focuses on Analytical chemistry and how it relates to Resonator and Terahertz radiation.
He interconnects Noble metal and Electron in the investigation of issues within Atomic physics. His Optics research is multidisciplinary, incorporating elements of Spectroscopy, Optoelectronics and Colloidal gold. His Surface plasmon resonance research is multidisciplinary, relying on both Particle, Local-density approximation and Plasmon, Surface plasmon.
Michel Broyer mainly investigates Atomic physics, Molecular physics, Analytical chemistry, Ionization and Spectroscopy. His Atomic physics study integrates concerns from other disciplines, such as Ion, Photoionization, Ionization energy and Cluster. His Ion research focuses on subjects like Electron, which are linked to Photochemistry.
His work carried out in the field of Molecular physics brings together such families of science as Ionic bonding, Dipole, Surface plasmon resonance and Optics. His Ionization research is multidisciplinary, incorporating elements of Electronic structure and Lithium. His Spectroscopy study combines topics in areas such as Excitation and Absorption spectroscopy.
Michel Broyer spends much of his time researching Spectroscopy, Analytical chemistry, Nanoparticle, Mass spectrometry and Surface plasmon resonance. His Spectroscopy research also works with subjects such as
His Nanoparticle research integrates issues from Optoelectronics, Dielectric and Particle. Michel Broyer has included themes like Molecular physics and Plasmon in his Surface plasmon resonance study. His Atomic physics study incorporates themes from Laser and Transition dipole moment.
His primary areas of study are Cluster, Spectroscopy, Optics, Surface plasmon resonance and Crystallography. His studies in Cluster integrate themes in fields like Absorption and Nanotechnology. The Spectroscopy study combines topics in areas such as Optical instrument and Analytical chemistry.
Resonance, Dipole and Discrete dipole approximation is closely connected to Silver nanoparticle in his research, which is encompassed under the umbrella topic of Optics. Much of his study explores Surface plasmon resonance relationship to Molecular physics. The study incorporates disciplines such as Time-dependent density functional theory, Chemical physics, Inorganic chemistry, Characterization and Mass spectrometry in addition to Crystallography.
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Direct measurement of the single-metal-cluster optical absorption.
A. Arbouet;D. Christofilos;N. Del Fatti;F. Vallée.
Physical Review Letters (2004)
Electron-phonon scattering in metal clusters.
Arnaud Arbouet;C. Voisin;D. Christofilos;Pierre Langot.
Physical Review Letters (2003)
Size-dependent electron-electron interactions in metal nanoparticles
C. Voisin;D. Christofilos;N. Del Fatti;F. Vallée.
Physical Review Letters (2000)
Optical Properties of Noble Metal Clusters as a Function of the Size: Comparison between Experiments and a Semi-Quantal Theory
E. Cottancin;G. Celep;J. Lermé;M. Pellarin.
Theoretical Chemistry Accounts (2006)
Ultrafast electron-electron scattering and energy exchanges in noble-metal nanoparticles
C. Voisin;D. Christofilos;P. A. Loukakos;N. Del Fatti.
Physical Review B (2004)
Evidence for icosahedral atomic shell structure in nickel and cobalt clusters. Comparison with iron clusters
M. Pellarin;B. Baguenard;J.L. Vialle;J. Lermé.
Chemical Physics Letters (1994)
Quenching of the Size Effects in Free and Matrix-Embedded Silver Clusters
J. Lermé;B. Palpant;B. Prével;M. Pellarin.
Physical Review Letters (1998)
Probing Elasticity at the Nanoscale: Terahertz Acoustic Vibration of Small Metal Nanoparticles
Vincent Juvé;Aurélien Crut;Paolo Maioli;Michel Pellarin.
Nano Letters (2010)
Plasmon coupling in silver nanocube dimers: resonance splitting induced by edge rounding.
Nadia Grillet;Delphine Manchon;Franck Bertorelle;Christophe Bonnet.
ACS Nano (2011)
Performances of Wang-Landau algorithms for continuous systems.
Pierre Poulain;Florent Calvo;Rodolphe Antoine;Michel Broyer.
Physical Review E (2006)
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