Optical trapping by Laguerre-Gaussian beams: Symmetries, stability and equilibria

TL;DR

This paper analyzes the optical forces exerted by Laguerre-Gaussian beams on spherical particles using the T-matrix formalism, exploring stability, equilibria, and dynamics near trapping points, including effects of Mie resonances.

Contribution

It introduces a combined theoretical approach to evaluate optical forces and analyze particle dynamics and stability in optical trapping with LG beams, including non-conservative effects.

Findings

Non-conservative dynamics for azimuthal LG beams.

Presence of conditionally stable equilibria stabilized by damping.

Mie resonances can alter trapping properties.

Abstract

We use the T-matrix formalism in combination with the method of far-field matching to evaluate the optical force exerted by Laguerre-Gaussian (LG) light beams on a spherical (Mie) particle. For both non-vortex and optical vortex LG beams, the theoretical results are used to analyze the optical-force-induced dynamics of the scatterer near the trapping points represented by the equilibrium (zero-force) positions. The regimes of linearized dynamics are described in terms of the stiffness matrix spectrum and the damping constant of the ambient medium. For the purely azimuthal LG beams, the dynamics is found to be locally non-conservative and is characterized by the presence of conditionally stable equilibria (unstable zero-force points that can be stabilized by the ambient damping). The effects related to the Mie resonances that under certain conditions manifest themselves as the points changing the trapping properties of the particles are discussed.