{\rtf1\ansi\deff0\deftab360

{\fonttbl
{\f0\fswiss\fcharset0 Arial}
{\f1\froman\fcharset0 Times New Roman}
{\f2\fswiss\fcharset0 Verdana}
{\f3\froman\fcharset2 Symbol}
}

{\colortbl;
\red0\green0\blue0;
}

{\info
{\author Biblio 7.x}{\operator }{\title Biblio RTF Export}}

\f1\fs24
\paperw11907\paperh16839
\pgncont\pgndec\pgnstarts1\pgnrestart
Dynamic formation of arrays of interacting optical spatial solitons under light-sheet illumination. Optics Letters, 50, 4318?4321 (2025202520252025).\par \par Bayesian Estimation of Experimental Parameters in Stochastic Inertial Systems: Theory, Simulations, and Experiments with Objects Levitated in Vacuum. Phys. Rev. Appl., 19, 064059 (2023202320232023).\par \par Tunable Soft-Matter Optofluidic Waveguides Assembled by Light. ACS Phot., 6, 403-410 (2019201920192019).\par \par A new type of microphotoreactor with integrated optofluidic waveguide based on solid-air nanoporous aerogels. Royal Society Open Science, 5, 180802 (2018201820182018).\par \par Optofluidic Dye Lasers Based on Holey Fibers: Modeling and PerformanceAnalysis. J. Lightwave. Technol., 36, 4114-4122 (2018201820182018).\par \par Reversible switching of wetting properties and erasable patterning of polymer surfaces using plasma oxidation and thermal treatment. Appl. Surf. Sci., 441, 841-852 (2018201820182018).\par \par Sensitivity of compositional measurement of high-pressure fluid mixtures using microcantilever frequency response. Sensors Actuators A, 278, 111-126 (2018201820182018).\par \par Effects of Infrared Optical Trapping on Saccharomyces cerevisiae in a Microfluidic System. Sensors, 17, 2640 (2017201720172017).\par \par Thermal tuning of spectral emission from optically trapped liquid-crystal droplet resonators. J. Opt. Soc. Am. B, 34, 1855-1864 (2017201720172017).\par \par Spectral tuning of lasing emission from optofluidic droplet microlasers using optical stretching. Opt. Express, 21, 21380-21394 (2013201320132013).\par \par Characterization of oil-producing microalgae using Raman spectroscopy. Laser Phys. Lett., 8, 701?709 (2011201120112011).\par \par Diffusive Mixing of Polymers Investigated by Raman Microspectroscopy andMicrorheology. Langmuir, 26, 14223-14230 (2010201020102010).\par \par Raman Microspectroscopy of Individual Algal Cells: Sensing Unsaturation of Storage Lipids in vivo. Sensors, 10, 8635?8651 (2010201020102010).\par \par Detecting Sequential Bond Formation Using Three-Dimensional Thermal Fluctuation Analysis. Chem. Phys. Chem., 10, 1541-1547 (2009200920092009).\par \par Direct Measurement of the Nonconservative Force Field Generated byOptical Tweezers. Phys. Rev. Lett., 103, 108101 (2009200920092009).\par \par Light at work: The use of optical forces for particlemanipulation, sorting, and analysis. Electophoresis, 29, 4813?4851 (2008200820082008).\par \par Surface delivery of a single nanoparticle under movingevanescent standing-wave illumination. New. J. Phys., 10, 113010 (2008200820082008).\par \par Behaviour of an optically trapped probe approaching a dielectric interface. J Mod. Optics, 50, 1615-1625 (2003200320032003).\par \par Theoretical comparison of optical traps created by standing wave and single beam. Opt. Commun., 220, 401-412 (2003200320032003).\par \par Simplified description of optical forces acting on a nanoparticle in the Gaussian standing wave. J. Opt. Soc. Am. A, 19, 1025-1034 (2002200220022002).\par \par Single beam trapping in front of reflective surfaces. Opt. Lett., 26, 1466?1468 (2001200120012001).\par \par Optical trapping of nanoparticles and microparticles using Gaussian standing wave. Opt. Lett., 24, 1448?1450 (1999199919991999).\par \par Optical trapping of Rayleigh particles using a Gaussian standing wave. Opt. Commun., 151, 273?285 (1998199819981998).\par \par }