Title :
Single and Multiple Microparticle Trapping Using Non-Gaussian Beams From Optical Fiber Nanoantennas
Author :
Decombe, Jean-Baptiste ; Mondal, Samir K. ; Kumbhakar, Dharmadas ; Pal, Sudipta Sarkar ; Fick, Jochen
Author_Institution :
Inst. Neel, Univ. Grenoble Alpes, Grenoble, France
Abstract :
Optical trapping of dielectric microparticles is reported using an optical tweezers based on two original chemically etched fiber nanoantenna. The nanoantenna converts Gaussian beam into nondiffracting type quasi-Bessel beam, which is used in trapping microparticles. Stable trapping in three distinct positions is observed for an antenna distance of 32.5 μm and for light powers as low as 1.3 mW. Optical trapping properties are studied by applying Boltzmann statistics to the particle position fluctuations. Harmonic trapping potentials with trap stiffness of 3.5 pN μm-1 are observed. The FDTD simulation results on the antenna optics are also included to understand the trapping mechanism.
Keywords :
Boltzmann equation; antennas; finite difference time-domain analysis; nanophotonics; optical fibres; radiation pressure; Boltzmann statistics; FDTD simulation; antenna distance; antenna optics; chemically etched fiber nanoantenna; dielectric microparticles; distance 32.5 mum; harmonic trapping potentials; light powers; multiple microparticle trapping; non-Gaussian beams; nondiffracting type quasi-Bessel beam; optical fiber nanoantennas; optical trapping properties; optical tweezer; particle position fluctuations; power 1.3 mW; single microparticle trapping; stable trapping; trap stiffness; trapping mechanism; Adaptive optics; Antennas; Charge carrier processes; Optical beams; Optical fibers; Optical vortices; Stimulated emission; Optical trapping; force measurements; nanofabrication; optical fiber devices;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2014.2358194
