Publications
Hollow gold nanorectangles: The roles of polarization and substrate. Journal of Chemical Physics. 2013 ;139.
. Homogeneous Line Width of the Different Vibronic Bands of Retinal Absorption in Bacteriorhodopsin by the Hole-Burning Technique. The Journal of Physical Chemistry [Internet]. 1996 ;100(8):2762 - 2765. Available from: http://dx.doi.org/10.1021/jp952971k
. Hot electron and phonon dynamics of gold nanoparticles embedded in a gel matrix. Chemical Physics Letters. 2001 ;343:55-63.
. Hot electron relaxation dynamics of gold nanoparticles embedded in MgSO4 powder compared to solution: The effect of the surrounding medium. Journal of Physical Chemistry B. 2002 ;106:945-955.
. How does a gold nanorod melt?. Journal of Physical Chemistry B. 2000 ;104:7867-7870.
. How long does it take to melt a gold nanorod? A femtosecond pump-probe absorption spectroscopic study. Chemical Physics Letters. 1999 ;315:12-18.
. Hyperoxia Induces Intracellular Acidification in Neonatal Mouse Lung Fibroblasts: Real-Time Investigation Using Plasmonically Enhanced Raman Spectroscopy. Journal of the American Chemical Society. 2016 ;138:3779–3788.
. Improving the Flow Cytometry-based Detection of the Cellular Uptake of Gold Nanoparticles. Analytical chemistry. 2019 .
. Inducing Cancer Cell Death by Targeting Its Nucleus: Solid Gold Nanospheres versus Hollow Gold Nanocages. Bioconjugate Chemistry. 2013 ;24:897-906.
. Influence of Steam Treatment on Dye-Titania Complex Formation and Photoelectric Conversion Property of Dye-Doped Titania Gel. Journal of Physical Chemistry C. 2011 ;115:2880-2887.
. Interfacial carriers dynamics of CdS nanoparticles. Journal of Physical Chemistry A. 1998 ;102:5652-5658.
. Intracellular assembly of nuclear-targeted gold nanosphere enables selective plasmonic photothermal therapy of cancer by shifting their absorption wavelength toward near-infrared region. Bioconjugate Chemistry . 2017 .
Kinetically controlled growth and shape formation mechanism of platinum nanoparticles. Abstracts of Papers of the American Chemical Society. 1998 ;215:U176-U176.
. Kinetics of the M-Intermediate in the Photocycle of Bacteriorhodopsin upon Chemical Modification with Surfactants. Photochemistry and Photobiology. 2010 ;86:316-323.
. Large Enhancement of Circular Dichroism Using an Embossed Chiral Metamaterial. arXiv preprint. 2016 .
. Laser Multiphoton Dissociation Ionization of Acrolein Clusters. The Journal of Physical Chemistry A [Internet]. 1997 ;101(20):3699 - 3701. Available from: http://dx.doi.org/10.1021/jp9605010
. Laser photothermal melting and fragmentation of gold nanorods: Energy and laser pulse-width dependence. Journal of Physical Chemistry A. 1999 ;103:1165-1170.
. Laser-induced shape changes of colloidal gold nanorods using femtosecond and nanosecond laser pulses. Journal of Physical Chemistry B. 2000 ;104:6152-6163.
. The Last Step in Converting the Surface Plasmonic Energy into Heat by Nanocages and Nanocubes on Substrates. Small. 2013 ;9:3934-3938.
. The 'lightning' gold nanorods: fluorescence enhancement of over a million compared to the gold metal. Chemical Physics Letters. 2000 ;317:517-523.
. Light-responsive plasmonic arrays consisting of silver nanocubes and a photoisomerizable matrix. ACS Appl Mater Interfaces. 2015 ;7(8):4902-12.
. Low-temperature retinal photoisomerization dynamics in bacteriorhodopsin. Journal of Physical Chemistry B. 1998 ;102:2303-2306.
. On the Mechanism of the Plasmonic Field Enhancement of the Solar-to-Electric Energy Conversion by the Other Photosynthetic System in Nature (Bacteriorhodopsin): Kinetic and Spectroscopic Study. Journal of Physical Chemistry C. 2010 ;114:15358-15363.
. Medium effect on the electron cooling dynamics in gold nanorods and truncated tetrahedra. Advanced Materials. 2003 ;15:393-+.
. Meniscus-assisted solution printing of large-grained perovskite films for high-efficiency solar cells. Nature Communications. 2017 .