Gregory V. Hartland

Transient Absorption Studies of Single Silver Nanocubes.
Journal of Physical Chemistry C (2008), 112(20), 7535-7539.

Dark-field microscopy studies of single metal nanoparticles: understanding the factors that influence the linewidth of the localized surface plasmon resonance.
Journal of Materials Chemistry (2008), 18(17), 1949-1960.

Optical studies of the dynamics of single metal nanoparticles.
Abstracts of Papers, 235th ACS National Meeting, New Orleans, LA, United States, April 6-10, 2008 (2008), PHYS-316.

The effect of size, shape and composition on the properties of metal nanoparticles. 
Abstracts of Papers, 235th ACS National Meeting, New Orleans, LA, United States, April 6-10, 2008 (2008), COLL-133.

Nanoparticle crystallinity. Is perfect better? Nature Materials (2007), 6(10), 716-718.

Correlated Rayleigh Scattering Spectroscopy and Scanning Electron Microscopy Studies of Au-Ag Bimetallic Nanoboxes and Nanocages.
Journal of Physical Chemistry C (2007), 111(34), 12558-12565.

Photothermal properties of gold nanoparticles.
Zeitschrift fuer Physikalische Chemie (Muenchen, Germany) (2007), 221(3), 361-376.

Time-resolved spectroscopy of silver nanocubes: observation and assignment of coherently excited vibrational modes.
Journal of Chemical Physics (2007), 126(9), 094709/1-094709/8.

Optical properties of nanoparticles with hollow structures: A single nanoparticle spectroscopy study.
Abstracts of Papers, 233rd ACS National Meeting, Chicago, IL, United States, March 25-29, 2007 (2007), INOR-117.

Vibrational Response of Au-Ag Nanoboxes and Nanocages to Ultrafast Laser-Induced Heating.
Nano Letters (2007), 7(4), 1059-1063.

Vibrational spectroscopy and energy relaxation of nanocubes, nanoboxes, and nanocages.
Proceedings of SPIE-The International Society for Optical Engineering (2006), 6325
(Physical Chemistry of Interfaces and Nanomaterials V), 632507/1-632507/8.

Gold nanostructures: engineering their plasmonic properties for biomedical applications.
Chemical Society Reviews (2006), 35(11), 1084-1094.

Crystal structure dependence of the elastic constants of gold nanorods.
Journal of Materials Chemistry (2006), 16(40), 3957-3963.

Plasmon resonances in Au-Ag nanoboxes studied by single nanoparticle spectroscopy.
Abstracts of Papers, 232nd ACS National Meeting, San Francisco, CA, United States, Sept. 10-14, 2006 (2006), PHYS-533.

Investigation of the photothermal properties and heat dissipation of gold nanocages in aqueous solution.
Abstracts of Papers, 232nd ACS National Meeting, San Francisco, CA, United States, Sept. 10-14, 2006 (2006), INOR-950.

Contributions from radiation damping and surface scattering to the linewidth of the longitudinal plasmon band of gold nanorods:
a single particle study. Physical Chemistry Chemical Physics (2006), 8(30), 3540-3546.

Optical Properties of Au-Ag Nanoboxes Studied by Single Nanoparticle Spectroscopy.
Journal of Physical Chemistry B (2006), 110(40), 19923-19928.

Coherent excitation of vibrational modes in metallic nanoparticles.
Annual Review of Physical Chemistry (2006), 57 403-430.

Controlled Synthesis of Nanoparticles in Microheterogeneous Systems, by
Vincenzo Turco Liveri. from the Series: Nanostructure Science and Technology, edited by David J. Lockwood.
Journal of the American Chemical Society (2006), 128(18), 6267-6268.

On the temperature stability of gold nanorods: comparison between thermal and ultrafast laser-induced heating.
Physical Chemistry Chemical Physics (2006), 8(7), 814-821.

Ultrafast Laser Studies of the Photothermal Properties of Gold Nanocages.
Journal of Physical Chemistry B (2006), 110(4), 1520-1524.

Coherent excitation of vibrational modes of gold nanorods.
Nanoparticle Assemblies and Superstructures (2006), 125-138.

Nanoparticle crystallinity: is perfect better?. Nature materials (2007), 6(10), 716-8.

Time-resolved spectroscopy of silver nanocubes: observation and assignment of coherently excited vibrational modes.
The Journal of chemical physics (2007), 126(9), 094709.

 

Posted 07/24/2008