Title :
Stand-Alone Three-Dimensional Optical Tweezers Based on Fibred Bowtie Nanoaperture
Author :
Hameed, Nyha M. ; El Eter, Ali ; Grosjean, Thierry ; Baida, Fadi I.
Author_Institution :
Dept. d´Opt. P.M. Duffieux, Univ. de Franche-Comte, Besancon, France
Abstract :
We study optical trapping of small particles based on the use of a bowtie nanoaperture antenna (BNA) engraved at the end of a metal-coated near-field optical microscope tip. Within the obtained light confinement, a 3-D trapping of latex nanoparticles is studied and quantified as a function of the incident light power. Good agreement between experimental and numerical results is obtained for a BNA operating in water at (λ = 1064 nm) that faithfully traps 250-nm-radius latex particles. Further numerical investigations are performed to study the dynamic of the trapping process in comparison with experimental results. In addition, numerical results for R = 100 nm and R = 30 nm-radii latex particles are presented and show that such a configuration has the potential to trap latex particles as small as 30 nm in radius.
Keywords :
aperture antennas; bow-tie antennas; nanoparticles; nanophotonics; optical fibres; optical microscopes; radiation pressure; water; fibred bowtie nanoaperture; incident light power; latex nanoparticles; light confinement; metal-coated near-field optical microscope tip; optical trapping; size 250 nm to 30 nm; small particles; stand-alone three-dimensional optical tweezers; water; wavelength 1064 nm; Biomedical optical imaging; Charge carrier processes; Force; Optical diffraction; Optical imaging; Optical polarization; Optical resonators; FDTD; Optical trapping; bowtie antenna; experiment; nano-antenna; nano-particles; optical fiber;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2014.2341011
