Dr. Jérémie Margueritat — Nanoparticle Low Frequency Vibration

Nanoparticles

Researcher unique identifier(s)

  • ORCID 0000-0003-2075-1875
  • ResearcherID I-1167-2012
  • ScopusID 16550090800

    • Publication List

    2020

    1. Anomalously low Rayleigh scattering by CdS/CdSe doped glasses; J. of Non-Crystalline Solids; 544; 120234
    2. Performances of the Lamb Model to Describe the Vibrations of Gold Quantum-Sized Clusters; J. Phys. Chem C ASAP
    3. Evaluation of modern Brillouin spectrometers for applications to biology; Biomedical Optics Express accepted
    4. On the Influence of Phase Change in Highly Loaded Frictional Contacts; Tribology Letters; 68, 54
    5. Inelastic Light Scattering by Long Narrow Gold Nanocrystals: When Size, Shape, Crystallinity, and Assembly Matter;  ACS Nano; 14, 4395 CNRS INC news
    6. Micromechanical imaging of dentin with Brillouin microscopy; Acta Biomaterialia ; 105, 214

    2019

    1. Revisiting Pressure-Induced Transitions in Mesoporous Anatase TiO2; J. Phys. Chem C; 123, 23488
    2. Inelastic Light Scattering by Multiple Vibrational Modes in Individual Gold Nanodimers; J. Phys. Chem. ; 123, 14834
    3. High-frequency mechanical properties of tumors measured by brillouin light scattering; Phys. Rev. Lett.; 122, 018101 PRL editor's suggestion and featured in physics; CNRS Highlight
    4. From localized to delocalized plasmonic modes, first observation of superradiant scattering in disordered semi-continuous metal films; Nanotechnology; 30, 1, 015706
    2018
    1. Acoustic Mode Hybridization in a Single Dimer of Gold Nanoparticles; Nano Letters; 18, 6, 3800-3806
    2. Correlated evolution of structure and mechanical loss of a sputtered silica film; Phys. Rev. Mat.; 2, 5, 053607
    3. Contact laws between nanoparticles: the elasticity of a nanopowder; Nanoscale; 10,2154-2161
    2017
    1. Mechanisms of resonant low frequency Raman scattering from metallic nanoparticle Lamb modes; J. Chem. Phys.; 146, 19, 194201
    2. Environmental effects on the natural vibrations of nanoplatelets: a high pressure study; Nanoscale; 9, 19, 6551-6557
    3. Inelastic Light Scattering Contribution to the Study of the Onset of Sintering of a Nanopowder; J. Phys. Chem. C; 121, 4, 2487-2494
    2016
    1. Mechanical Coupling in Gold Nanoparticles Supermolecules Revealed by Plasmon-Enhanced Ultralow Frequency Raman Spectroscopy; Nano Letters, 16, 6, 3843-3849
      2. CNRS National Institute of Physics Highlight
    2. The mass load effect on the resonant acoustic frequencies of colloidal semiconductor nanoplatelets; Nanoscale; 8, 27, 13251-13256
    2014
    1. Elastic Moduli of Permanently Densified Silica Glasses; Scientific Reports; 4, 7193
    2. Sorting of Enhanced Reference Raman Spectra of a Single Amino Acid Molecule; J. Phys. Chem. C; 118, 31, 17975-17982
    3. Optical and Acoustic Vibrations Confined in Anatase TiO2 Nanoparticles under High-Pressure; J. Phys. Chem., 118, 19, 2014
    2013
    1. In situ Brillouin study of sodium silicate glasses under pressure; J. Chem. Phys.; 139, 7, 074501, 2013
    2. Permanent densification of compressed silica glass: a Raman-density calibration curve; J. Phys. Cond. Matter; 25, 2, 025402, 2013
    3. High temperature structural and magnetic properties of cobalt nanorods; J. Solid State Chem.; 197, 297-303, 2013
    2012
    1. Discerning the Origins of the Amplitude Fluctuations in Dynamic Raman Nanospectrocopy; J. Phys. Chem. C; 116, 51, 26919-26923, 2012
    2. Quasi-Free Nanoparticle Vibrations in a Highly Compressed ZrO2 Nanopowder; J. Phys. Chem. C; 116, 41, 22043-22050, 2012
    3. Progressive transformations of silica glass upon densification; J. Chem. Phys.; 137, 12, 124505 2012
    2011
    1. Influence of the Number of Nanoparticles on the Enhancement Properties of Surface-Enhanced Raman Scattering Active Area: Sensitivity versus Repeatability; ACS Nano; 5, 3, 1630-1638, 2011
    2005 — 2010
    1. Nano-gold biosynthesis by silica-encapsulated micro-algae: a "living" bio-hybrid material; J. Mat. Chem.; 20, 42, 9342-9347, 2010
    2. Sculpting nanometer-sized light landscape with plasmonic nanocolumns; J. Chem. Phys.; 131, 22, 224707, 2009
    3. Acousto-plasmonic Hot Spots in Metallic Nano-Objects; NANO LETTERS; 9, 11, 3914-3921, 2009
    4. Tuning an Optical Dimer Nanoantenna by Electrically Controlling its Load Impedance; NANO LETTERS; 9, 11, 3914-3921, 2009
    5. Surface enhanced Raman scattering of silver sensitized cobalt nanoparticles in metal-dielectric nanocomposites; NANOTECHNOLOGY; 19, 37, 375701, 2008
    6. Acoustic vibration modes and electron-lattice coupling in self-assembled silver nanocolumns; NANO LETTERS; 8, 5, 1296-1302, 2008
    7. Size dispersion effects on the low-frequency Raman scattering of quasispherical silver nanoparticles: Experiment and Theory; Phys. Rev. B; 76, 23, 235419, 2007
    8. From silver nanolentils to nanocolumns: surface plasmon-polaritons and confined acoustic vibrations; Applied. Phys. A; 89, 2, 369-372, 2007
    9. Observation of Co/CoO nanoparticles below the critical size for echange bias; J. Applied Phys.; 101, 11, 113913, 2007
    10. Interface effects in the magneto-optical properties of Co nanoparticles in dielectric matrix; Applied Phys. Lett.; 90, 18, 182506, 2007
    11. Surface plasmon and vibrations of self-assembled silver nanocolumns; NANO LETTERS; 6, 9, 093107, 2006
    12. Production of self-aligned metal nanocolumns embedded in an oxide matrix film; Applied Phys. Lett.; 88, 9, 093107, 2006
    13. Critical size for exchange bias in ferromagnetic-antiferromagnetic particles; Applied Phys. Lett.; 87, 1, 012501, 2005