Publications
Ultrafast Processes in Chemistry and Photobiology. Blackwell Science; 1995.
. Applications of gold nanorods for cancer imaging and photothermal therapy. In: Methods in Molecular Biology. Vol. 624. Methods in Molecular Biology. Springer; 2010. pp. 343-357. Available from: http://dx.doi.org/10.1007/978-1-60761-609-2_23
. Fluorescent Quenching Gold Nanoparticles: Potential Biomedical Applications. In: Metal Enhanced Fluorescence. Metal Enhanced Fluorescence. Wiley Online Library; 2010. pp. 573-599. Available from: http://dx.doi.org/10.1002/9780470642795.ch20
. Optically detected coherent picosecond lattice oscillations in two dimensional arrays of gold nanocrystals of different sizes and shapes induced by femtosecond laser pulses. Proceedings of SPIE [Internet]. 2005 ;5927:592701. Available from: http://dx.doi.org/10.1117/12.620501
. Activation energy of the reaction between hexacyanoferrate(III) and thiosulfate ions catalyzed by platinum nanoparticles. Journal of Physical Chemistry B. 2000 ;104:10956-10959.
. Aggregation of Gold Nanoframes Reduces, Rather Than Enhances, SERS Efficiency Due to the Trade-Off of the Inter- and Intraparticle Plasmonic Fields. Nano Letters. 2009 ;9:3025-3031.
. Alloy formation of gold-silver nanoparticles and the dependence of the plasmon absorption on their composition. Journal of Physical Chemistry B. 1999 ;103:3529-3533.
. Application of liquid waveguide to Raman spectroscopy in aqueous solution. Applied Spectroscopy. 1998 ;52:1364-1367.
. Aspect Ratio Dependence of the Enhanced Fluorescence Intensity of Gold Nanorods: Experimental and Simulation Study. The Journal of Physical Chemistry B [Internet]. 2005 ;109(34):16350 - 16356. Available from: http://dx.doi.org/10.1021/jp052951a
. The assignment of the different infrared continuum absorbance changes observed in the 3000-1800-cm(-1) region during the bacteriorhodopsin photocycle. Biophysical Journal. 2004 ;87:2676-2682.
. Au nanoparticles target cancer. Nano Today. 2007 ;2:18-29.
. Bacteriorhodopsin O-state Photocycle Kinetics: A Surfactant Study. Photochemistry and Photobiology. 2010 ;86:70-76.
. Bacteriorhodopsin-based photo-electrochemical cell. Biosensors & Bioelectronics. 2010 ;26:620-626.
. Bacteriorhodopsin/TiO(2) nanotube arrays hybrid system for enhanced photoelectrochemical water splitting. Energy & Environmental Science. 2011 ;4:2909-2914.
. Binding of, and Energy-Transfer Studies from Retinal to, Organic Cations in Regenerated Reduced Bacteriorhodopsin. The Journal of Physical Chemistry [Internet]. 1994 ;98(37):9339 - 9344. Available from: http://dx.doi.org/10.1021/j100088a040
. The Ca2+ binding to deionized monomerized and to retinal removed bacteriorhodopsin. Biophysical journal. 1995 ;69(5):2056-9.
. Calcium and Magnesium Binding in Native and Structurally Perturbed Purple Membrane. The Journal of Physical Chemistry [Internet]. 1996 ;100(3):929 - 933. Available from: http://dx.doi.org/10.1021/jp952951i
. Calculated absorption and scattering properties of gold nanoparticles of different size, shape, and composition: Applications in biological imaging and biomedicine. Journal of Physical Chemistry B. 2006 ;110:7238-7248.
. 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.
. Cancer cells assemble and align gold nanorods conjugated to antibodies to produce highly enhanced, sharp, and polarized surface Raman spectra: A potential cancer diagnostic marker. Nano Letters. 2007 ;7:1591-1597.
. Carbon-supported spherical palladium nanoparticles as potential recyclable catalysts for the Suzuki reaction. Journal of Catalysis. 2005 ;234:348-355.
. Catalysis of the retinal subpicosecond photoisomerization process in acid purple bacteriorhodopsin and some bacteriorhodopsin mutants by chloride ions. Biophysical journal. 1996 ;71(3):1545-53.
. Catalysis with transition metal nanoparticles in colloidal solution: Nanoparticle shape dependence and stability. Journal of Physical Chemistry B. 2005 ;109:12663-12676.
. Change in titania structure from amorphousness to crystalline increasing photoinduced electron-transfer rate in dye-titania system. Journal of Physical Chemistry C. 2007 ;111:9008-9011.
. Changing catalytic activity during colloidal platinum nanocatalysis due to shape changes: Electron-transfer reaction. Journal of the American Chemical Society. 2004 ;126:7194-7195.
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