Omnidirectional gradient force optical trapping in dielectric nanocavities by inverse design

TL;DR

This paper introduces a novel inverse-designed dielectric nanocavity that achieves omnidirectional optical trapping of sub-wavelength particles using gradient forces, enabling new applications in nanophotonics and quantum physics.

Contribution

It presents the first practical design of lossless, integrated dielectric nanocavities capable of omnidirectional trapping of nanoscale particles solely with gradient forces.

Findings

Successfully traps 15 nm particles overcoming thermal fluctuations

Designs operate at short-wave infrared and near-infrared wavelengths

Enables deep trapping potentials for sub-wavelength particles

Abstract

Optical trapping enables precise control of individual particles of different sizes, such as atoms, molecules, or nanospheres. Optical tweezers provide free-space omnidirectional optical trapping of objects in laboratories around the world. As an alternative to standard macroscopic setups based on lenses, which are inherently bound by the diffraction limit, plasmonic and photonic nanostructures promise trapping by near-field optical effects on the extreme nanoscale. However, the practical design of lossless waveguide-coupled nanostructures capable of trapping sub-wavelength-sized particles in all spatial directions has until now proven insurmountable. In this work, we demonstrate an omnidirectional optical trap realized by inverse-designing fabrication-ready integrated dielectric nanocavities. The sub-wavelength optical trap is designed to rely solely on the gradient force and is thus particle-size agnostic. In particular, we show how a trapped particle with a radius of 15 nm experiences a force strong enough to overcome room-temperature thermal fluctuations. Furthermore, through the robust inverse design framework, we tailor manufacturable devices operating at short-wave infrared and near-infrared wavelengths. Our results open a new regime of levitated optical trapping by achieving a deep trapping potential capable of trapping single sub-wavelength particles in all directions using optical gradient forces. We anticipate potentially groundbreaking applications of the optimized optical trapping system for biomolecular analysis in aqueous environments, levitated cavity-optomechanics, and cold atom physics, constituting an important step towards realizing integrated bio-nanophotonics and mesoscopic quantum mechanical experiments.