{\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
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 Rapid detection of antibiotic sensitivity of Staphylococcus aureus by Raman tweezers. Eur. Phys. J. Plus, 136, 233 (2021202120212021).\par \par Tunable Soft-Matter Optofluidic Waveguides Assembled by Light. ACS Phot., 6, 403-410 (2019201920192019).\par \par Detection of chloroalkanes by surface-enhanced raman spectroscopy in microfluidic chips. Sensors, 18, 3212 (2018201820182018).\par \par Diffusing up the Hill: Dynamics and Equipartition in Highly Unstable Systems. Phys. Rev. Lett., 121, 23601 (2018201820182018).\par \par Three-dimensional holographic optical manipulation through a high-numerical-aperture soft-glass multimode fibre. Nature Photon., 12, 33?39 (2018201820182018).\par \par Transverse spin forces and non-equilibrium particle dynamics in a circularly polarized vacuum optical trap. Nature Commun., 9, 5453 (2018201820182018).\par \par Differentiation between Staphylococcus aureus and Staphylococcus epidermidis strains using Raman spectroscopy. Future Microbiology, 12, 10 (2017201720172017).\par \par Dynamics of an optically bound structure made of particles of unequal sizes. Opt. Lett., 42, 1436-1439 (2017201720172017).\par \par Morphological and Production Changes in Planktonic and Biofilm Cells Monitored Using SEM and Raman Spectroscopy. Microscopy and Microanalysis, 23, S1 (2017201720172017).\par \par Rapid identification of staphylococci by Raman spectroscopy. Sci. Rep., 7, 14846 (2017201720172017).\par \par Thermally induced micro-motion by inflection in optical potential. Sci. Rep., 7, 1697 (2017201720172017).\par \par Direct measurement of the temperature profile close to an optically trapped absorbing particle. Opt. Lett., 41, 870-873 (2016201620162016).\par \par Noise-to-signal transition of a Brownian particle in the cubic potential: II. optical trapping geometry. Journal of Optics, 18, 065402 (2016201620162016).\par \par Quantitative Raman Spectroscopy Analysis of Polyhydroxyalkanoates Produced by Cupriavidus necator H16. Sensors, 16, 1808 (2016201620162016).\par \par Aberration resistant axial localization using a self-imaging of vortices. Opt. Express, 23, 15316?15331 (2015201520152015).\par \par Complex rotational dynamics of multiple spheroidalparticles in a circularly polarized, dual beam trap. Opt. Express, 23, 7273-7287 (2015201520152015).\par \par Cryo-SEM and Raman Spectroscopy Study of the Involvement of Polyhydroxyalkanoates in Stress Response of Bacteria. Microscopy and Microanalysis, 21, 183-184 (2015201520152015).\par \par Identification of individual biofilm-forming bacterial cells using Raman tweezers. J. Biomed. Opt., 20, (2015201520152015).\par \par Influence of Culture Media on Microbial Fingerprints Using Raman Spectroscopy. Sensors, 15, 29635-29647 (2015201520152015).\par \par Non-spherical gold nanoparticles trapped in optical tweezers: shape matters. Opt. Express, 23, 8179-8189 (2015201520152015).\par \par Optical trapping in secondary maxima of focused laser beam. J. Quant. Spectrosc. Radiat. Transf., 162, 114 - 121 (2015201520152015).\par \par Three-Dimensional Optical Trapping of a Plasmonic Nanoparticle using Low Numerical Aperture Optical Tweezers. Sci. Rep., 5, 8106 (2015201520152015).\par \par Candida parapsilosis Biofilm Identification by RamanSpectroscopy. Int. J. Mol. Sci., 15, 23924-23935 (2014201420142014).\par \par Optical sorting of nonspherical and living microobjects in moving interference structures. Opt. Express, 22, 29746-29760 (2014201420142014).\par \par Experimental demonstration of optical transport, sorting and self-arrangement using a `tractor beam'. Nature Photon., 7, 123-127 (2013201320132013).\par \par Following the mechanisms of bacteriostatic versus bacericidal action using Raman spectroscopy. Molecules, 18, 13188-13199 (2013201320132013).\par \par Metallic nanoparticles in a standing wave: optical forceand heating. J. Quant. Spectrosc. Radiat. Transf., 126, 84-90 (2013201320132013).\par \par Optical forces in a non-diffracting vortex beam. J. Quant. Spectrosc. Radiat. Transf., 126, 78-83 (2013201320132013).\par \par Optical manipulation of aerosol droplets using aholographic dual and single beam trap. Opt. Lett., 38, 4601-4604 (2013201320132013).\par \par Optical forces induced behavior of a particle in a non-diffracting vortex beam. Opt. Express, 20, 24304-24319 (2012201220122012).\par \par Speed enhancement of multi-particle chain in a travelingstanding wave. Appl. Phys. Lett., 100, 051103 (2012201220122012).\par \par Parametric study of optical forces acting upon nanoparticles in a single, or a standing, evanescentwave. J. Opt., 13, 044016:1?9 (2011201120112011).\par \par Static and dynamic behavior of two optically boundmicroparticles in a standing wave. Opt. Express, 19, 19613?19626 (2011201120112011).\par \par Experimental and theoretical determination of opticalbinding forces. Opt. Express, 18, 25389?25402 (2010201020102010).\par \par Particle jumps between optical traps in a one-dimensionaloptical lattice. New. J. Phys., 12, 083001:1?20 (2010201020102010).\par \par Surface delivery of a single nanoparticle under movingevanescent standing-wave illumination. New. J. Phys., 10, 113010 (2008200820082008).\par \par Optical forces acting on a nanoparticle placed into an interference evanescent field. Opt. Commun., 275, 409?420 (2007200720072007).\par \par Optical forces generated by evanescent standing waves and their usage for sub-micron particle delivery. Appl. Phys. B, 84, 157?165 (2006200620062006).\par \par An optical nanotrap array movable over a milimetre range. Appl. Phys. B, 84, 197?203 (2006200620062006).\par \par Optical sorting and detection of sub-micron objects in a motional standing wave. Phys. Rev. B, 74, 035105:1-6 (2006200620062006).\par \par }