Arthur Dogariu |
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| Research Scholar, MAE Dept., Princeton University | |
| Office: | (609) 258-9344 |
| Email: | adogariu@princeton.edu |
| URL: | http://www.princeton.edu/~adogariu/ |
| U.S. Mail: | Princeton University, MAE Dept., EQUAD D430, Olden Street, Princeton, NJ 08544 |
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Biophotonics – Molecular optical spectroscopy and detection:
“Real-time monitoring of blood using coherent anti-Stokes Raman spectroscopy,” J. Biomed. Opt. 13, 54004 (2008).
“Real-time detection of bacterial spores using Coherent anti-Stokes Raman Spectroscopy,” J. Appl. Phys. 103, 036103 (2008).
“Time-resolved coherent anti-Stokes Raman scattering spectroscopy with a photonic crystal fiber based light source,” to be submitted (2009).
“Sensitive femtosecond CARS discrimination between 2,6 Dipicolinic acid and 3,5 Dipicolinic acid,” Opt. Lett., Vol. 31, No. 21, 3176 (2006).
“Optimizing the Laser Pulse Configuration for Coherent Raman Spectroscopy,” Science 316, 265 (2007).
Organic lasers – semiconducting polymers:
“Photophysics of poly(2, 3-diphenyl-5-hexyl-p-phenylene vinylene),” Phys. Rev. B (Condensed Matter) 61 (23), 16183-6 (2000).
“Ultrafast detection of charged photocarriers in conjugated polymers,” Phys. Rev. B (Condensed Matter) 61(14), 9373-9 (2000).
“Excited state spectral and dynamics studies of MEH-PPV,” Synthetic Metals 101, 202-3 (1999).
“Time-Resolved Förster Energy Transfer in Polymer Blends,” Synthetic Metals 100 (1), 95-100 (1999).
“Picosecond Time-Resolved Spectroscopy of the Excited State in a Soluble Derivative of Poly(phenylene vinylene): Origin of the Bimolecular decay,” Phys. Rev. B (Condensed Matter), Vol. 58, No. 16, 10218 (1998).
Nanophotonics:
“Delay in Light Transmission through Small Apertures,” Opt. Lett. 26, 450 (2001).
“Optical pulse propagation through metallic nano-apertures,“ Applied Physics B, 74 [Suppl.], S69 (2002).
“Reducing Far-field Diffraction by Structured Apertures,” Opt. Comm., Vol. 220, No. 4-6, 223 (2003).
Atomic Spectroscopy & Plasma Dynamics:
“Velocity Measurements in Unseeded Air Flows by Microwave Scattering from a Laser Generated Micro Volume Plasma,” AIAA Journal, submitted
“Direct Measurement of Electron-Loss Rate in Air,” in preparation
Fast Light - Wave propagation in dispersive media:
“Gain-assisted superluminal light propagation,” Nature 406, 277-9 (2000).
“Transparent Anomalous Dispersion and Superluminal Light Pulse Propagation at a Negative Group Velocity,” Phys. Rev. A (Atomic, Molecular and Optical Physics), 63 (5), 053806-12, (2001).
“Superluminal light pulse propagation via rephasing in a transparent anomalously dispersive medium,” Optics Express 8, 344-350 (2001).
“Signal velocity, causality, and quantum noise in superluminal light pulse propagation,” Phys. Rev. Lett., 86, 3925 (2001).
Nonlinear Optics:
“Purely Refractive Transient Energy Transfer Via Stimulated Rayleigh Wing Scattering,” J. Opt. Soc. Am. B, Vol. 14, No. 4, 796 (1997).
“Low frequency Raman gain measurements using chirped pulses,” Optics Express, Vol. 1, No. 3, p. 73 (1997).
Optical Communication:
“Correlated photon generation for quantum cryptography,” NEC R&D Journal, Special Issue 44, 294 (2003).
“PMD Compensation via real-Time Phase Retrieval from Spectral Interference,” Opt. Comm., 282, 3706 (2009).