Nanovortex-driven all-dielectric optical diffusion boosting and sorting concept for lab-on-a-chip platforms

TL;DR

This paper introduces a nanophotonic platform using dielectric nanoantennas to generate nanovortices that enhance particle diffusion and enable precise nanoparticle sorting in microfluidic devices, advancing lab-on-a-chip technologies.

Contribution

It presents a novel dielectric nanoantenna design that creates subwavelength optical nanovortices for improved particle manipulation and sorting without moving parts.

Findings

Nanovortex size is an order of magnitude smaller than conventional methods.

Efficient spiral motion of nanoparticles driven by optical forces.

Enables nanomixing and precise nanoparticle sorting in microfluidic environments.

Abstract

The ever-growing field of microfluidics requires precise and flexible control over fluid flow at the micro- and nanoscales. Current constraints demand a variety of controllable components for performing different operations inside closed microchambers and microreactors. In this context, novel nanophotonic approaches can significantly enhance existing capabilities and provide new functionalities via finely tuned light-matter interaction mechanisms. Here we propose a novel design, featuring a dual functionality on-chip: boosted optically-driven particle diffusion and nanoparticle sorting. Our methodology is based on a specially designed high-index dielectric nanoantenna, which strongly enhances spin-orbit angular momentum transfer from an incident laser beam to the scattered field. As a result, exceptionally compact, subwavelength optical nanovortices are formed and drive spiral motion of peculiar plasmonic nanoparticles via the efficient interplay between curled spin optical forces and radiation pressure. The nanovortex size is an order of magnitude smaller than that provided by conventional beam-based approaches. The nanoparticles mediate nano-confined fluid motion enabling nanomixing without a need of moving bulk elements inside a microchamber. Moreover, precise sorting of gold nanoparticles, demanded for on-chip separation and filtering, can be achieved by exploiting the non-trivial dependence of the curled optical forces on the nanoobject size. Altogether, this study introduces a versatile platform for further miniaturization of moving-part-free, optically driven microfluidic chips for fast chemical synthesis and analysis, preparation of emulsions, or generation of chemical gradients with light-controlled navigation of nanoparticles, viruses or biomolecules.