Trapping multiple absorbing particles in air using an optical fiber by photophoretic forces

TL;DR

This paper demonstrates optical trapping of multiple absorbing particles in air using photophoretic forces with a Gaussian beam focused by various lenses, analyzing how focal length affects trapping efficiency and particle size.

Contribution

It introduces a novel method of trapping multiple particles in air via photophoretic forces using adjustable lens systems and provides a numerical model explaining the trapping dynamics.

Findings

Particle chains form at specific focal lengths.

The trapping range varies with lens focal length.

Average particle size decreases with increasing focal length.

Abstract

We demonstrate photophoretic force-based optical trapping of multiple absorbing particles in air by loosely focusing a Gaussian beam with a series of convex lenses of different focal lengths, and investigate the dependence of the number of trapped particles and their sizes on the focal length. We observe the formation of particle chains at a particular focal length, and measure the dynamic range of optical trapping for each lens system. We then develop a numerical simulation to explain the observed dynamic range of trapping by estimating the temperature distribution across a particle surface, and determining the photophoretic force. Our simulation results are in reasonable agreement with experimental results. Interestingly, we also observe that the average size of trapped particles reduces as we increase the lens focal lengths, which suggests that intensity gradients may somehow be involved in the mechanism of photophoretic trapping.