Higher order microfibre modes for dielectric particle trapping and propulsion

TL;DR

This paper demonstrates that higher order microfibre modes can significantly enhance optical trapping and propulsion of dielectric particles, offering faster manipulation compared to fundamental modes, with potential applications in quantum networks.

Contribution

The study introduces the use of higher order microfibre modes for improved optical trapping and propulsion of particles, surpassing fundamental mode capabilities.

Findings

Higher order modes extend evanescent fields and increase field amplitude.

Particles are propelled faster in higher order mode fields.

Experimental results show up to 8 times faster propulsion with higher order modes.

Abstract

Optical manipulation in the vicinity of optical micro- and nanofibres has shown potential across several fields in recent years, including microparticle control, and cold atom probing and trapping. To date, most work has focussed on propagation of the fundamental mode through the fibre. However, along the maximum mode intensity axis, higher order modes have a longer evanescent field extension and larger field amplitude at the fibre waist compared to the fundamental mode, opening up new possibilities for optical manipulation and particle trapping. In this work, we demonstrate a microfibre/optical tweezers compact system for trapping and propelling dielectric particles based on the excitation of the first group of higher order modes at the fibre waist. Single polystyrene particles were trapped and propelled in the evanescent fields of higher order and fundamental modes near the surface of microfibres. Speed enhancement of particle propulsion was observed for the higher order modes compared to the fundamental mode for particles ranging from 1 {\mu}m to 5 {\mu}m in diameter. The optical propelling velocity of a single, 3 {\mu}m polystyrene particle was found to be 8 times faster under the higher order evanescent field than the fundamental mode field for a waist power of 25 mW. Experimental data and dynamic interactions between the evanescent field of these two different fibre modes and the particles are supported by theoretical calculations. This work can be extended to trapping and manipulation of laser-cooled atoms for quantum networks.