Abstract EN:

This work deals with theoretical modeling of optical forces on micro-meter scale objects using exact electromagnetic calculations. In the first part, we derive and review the two approximate techniques commonly used to calculate optic in the two extreme size domains : the Rayleigh approximation for dealing with particles considerably smaller than the wavelength, [lambda] , of the trapping radiation, and the geometric optics approximation which applies to particles much larger than [lambda]. We then illustrate the limits of these approximate techniques via a comparison with the exact calculations that we have developed. In the second part, we consider optical traps containing multiple particles. For such studies we couple our exact calculation technique with exact solutions of the multi-scattering equations in order to evaluate the optically induced forces that appear between particles in multiparticle traps. Most of our applications to date concern homogeneous spherical trapped particles, and a the third part studies the extension to more general particles like coated spheres which can be used to model biological organites like cells. The last part concerns the applications of theoretical modeling to the rapidly developing field of optical tweezers for mico-meter scale manipulation.