Viscoelastic dynamics of nanoparticles optically trapped in moving fringe pattern in air-filled hollow-core fiber

TL;DR

This paper demonstrates the optical trapping and transport of nanoparticles within a moving interference pattern in hollow-core fiber, revealing a drag-trapping phenomenon influenced by viscous forces, with potential applications in nanoparticle characterization and sensing.

Contribution

It introduces a novel drag-trapping mechanism for nanoparticles in a moving fringe pattern within hollow-core fiber, supported by an analytical model matching experimental results.

Findings

Particle velocity oscillates due to trapping and drag forces.

Average particle velocity is lower than fringe velocity.

Control achieved by adjusting power imbalance.

Abstract

We report optical trapping and transport of nanoparticles in a moving interference pattern in hollow-core photonic crystal fiber at atmospheric pressure, when competition between trapping and drag forces causes the particle velocity to oscillate as it is momentarily captured and accelerated by each passing fringe, followed by release and deceleration by viscous forces. As a result the average particle velocity is lower than the fringe velocity. We refer to this phenomenon as drag-trapping. An analytical model of the resulting motion shows excellent agreement with experiment. Additional control is possible by introducing an imbalance in the backward and forward powers. The high precision of this new technique makes it of interest for example in characterizing nanoparticles, exploring viscous drag forces in different gases and liquids, and temperature sensing.