Title :
Slow bloch mode cavity for optical trapping
Author :
Benyattou, T. ; Gerelli, E. ; Milord, L. ; Jamois, C. ; Harouri, A. ; Chevalier, C. ; Seassal, Christian ; Belarouci, A. ; Letartre, Xavier ; Viktorovitch, P.
Author_Institution :
Inst. des Nanotechnol. de Lyon (INL), Univ. de Lyon, Villeurbanne, France
Abstract :
In this paper, we will present a new kind of structure that has the ability to trap nanometric particles and presents big capture cross section. This approach relies on the use of slow Bloch mode in a photonic crystal cavity. We will show how a new kind of design allows for an easy coupling of this kind of structure. FDTD modeling of the optical forces will be presented. We will show that the light intensity modulation related to the periodicity of the photonic crystal gives rise to strong gradient forces that are able to trap small nanoparticles in a large cavity. Experimental results validating this approach will be presented.
Keywords :
finite difference time-domain analysis; intensity modulation; nanoparticles; nanophotonics; optical design techniques; optical modulation; photonic crystals; radiation pressure; FDTD modeling; capture cross section; gradient forces; light intensity modulation; nanometric particles; optical forces; optical trapping; periodicity; photonic crystal; photonic crystal cavity; slow Bloch mode cavity; small nanoparticles; Cavity resonators; Charge carrier processes; Integrated optics; Microcavities; Optical diffraction; Photonic crystals; Q-factor; nanotweezer; optical forces; photonic crystal; slow Bloch mode;
Conference_Titel :
Transparent Optical Networks (ICTON), 2013 15th International Conference on
Conference_Location :
Cartagena
DOI :
10.1109/ICTON.2013.6602774
