Publications
. Probing the primary event in the photocycle of photoactive yellow protein using photochemical hole-burning technique. Photochemistry and Photobiology. 2000 ;72:639-644.
. Fourier Transform Infrared Spectroscopic Studies of the Effect of Ca2+ Binding on the States of Aspartic Acid Side Chains in Bacteriorhodopsin. The Journal of Physical Chemistry [Internet]. 1995 ;99(19):7776 - 7781. Available from: http://dx.doi.org/10.1021/j100019a066
. Thermal reshaping of gold nanorods in micelles. Journal of Physical Chemistry B. 1998 ;102:9370-9374.
. Temperature-dependent size-controlled nucleation and growth of gold nanoclusters. Journal of Physical Chemistry A. 1999 ;103:10255-10259.
. 5-Fluorouracil induces plasmonic coupling in gold nanospheres: new generation of chemotherapeutic agents. J. Nanomed. Nanotechnol. 2012 ;3:1000146/1-1000146/7.
. The 'lightning' gold nanorods: fluorescence enhancement of over a million compared to the gold metal. Chemical Physics Letters. 2000 ;317:517-523.
. Hot electron and phonon dynamics of gold nanoparticles embedded in a gel matrix. Chemical Physics Letters. 2001 ;343:55-63.
. 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
. Large Enhancement of Circular Dichroism Using an Embossed Chiral Metamaterial. arXiv preprint. 2016 .
On-Resonance Chiral Metamaterial for Chiroptical Sensing at the Molecular Level. CLEO: QELS Fundamental Science. 2017 .
. Effect of colloidal nanocatalysis on the metallic nanoparticle shape: The Suzuki reaction. Langmuir. 2005 ;21:2027-2033.
. Some aspects of colloidal nanoparticle stability, catalytic activity, and recycling potential. Topics in Catalysis. 2008 ;47:15-21.
. Raman Studies on the Interaction of the Reactants with the Platinum Nanoparticle Surface during the Nanocatalyzed Electron Transfer Reaction. The Journal of Physical Chemistry B [Internet]. 2005 ;109(39):18460 - 18464. Available from: http://dx.doi.org/10.1021/jp053526k
. Changing catalytic activity during colloidal platinum nanocatalysis due to shape changes: Electron-transfer reaction. Journal of the American Chemical Society. 2004 ;126:7194-7195.
. Effect of catalytic activity on the metallic nanoparticle size distribution: Electron-transfer reaction between Fe(CN)(6) and thiosulfate ions catalyzed by PVP-platinum nanoparticles. Journal of Physical Chemistry B. 2003 ;107:12416-12424.
. FTIR study of the mode of binding of the reactants on the Pd nanoparticle surface during the catalysis of the Suzuki reaction. Journal of Physical Chemistry B. 2005 ;109:4357-4360.
. Can the observed changes in the size or shape of a colloidal nanocatalyst reveal the nanocatalysis mechanism type: Homogeneous or heterogeneous?. Topics in Catalysis. 2008 ;48:60-74.
. Effect of Colloidal Catalysis on the Nanoparticle Size Distribution: Dendrimer−Pd vs PVP−Pd Nanoparticles Catalyzing the Suzuki Coupling Reaction. The Journal of Physical Chemistry B [Internet]. 2004 ;108(25):8572 - 8580. Available from: http://dx.doi.org/10.1021/jp037169u
. Shape-dependent catalytic activity of platinum nanoparticles in colloidal solution. Nano Letters. 2004 ;4:1343-1348.
. Catalysis with transition metal nanoparticles in colloidal solution: Nanoparticle shape dependence and stability. Journal of Physical Chemistry B. 2005 ;109:12663-12676.
. Carbon-supported spherical palladium nanoparticles as potential recyclable catalysts for the Suzuki reaction. Journal of Catalysis. 2005 ;234:348-355.
. Effect of nanocatalysis in colloidal solution on the tetrahedral and cubic nanoparticle SHAPE: Electron-transfer reaction catalyzed by platinum nanoparticles. Journal of Physical Chemistry B. 2004 ;108:5726-5733.
. Effect of catalysis on the stability of metallic nanoparticles: Suzuki reaction catalyzed by PVP-palladium nanoparticles. Journal of the American Chemical Society. 2003 ;125:8340-8347.
. Self-Assembled Nanostructured Photoanodes with Staggered Bandgap for Efficient Solar Energy Conversion. ACS nano. 2014 .
. Bandgap bowing in Ta-W-O system for efficient solar energy conversion: Insights from density functional theory and X-ray diffraction. Applied Physics Letters. 2013 ;103.