Nanoparticle Photo-Ejection from Liquid via Excited Plasmonic Supercavitation

TL;DR

This paper introduces a novel laser-based method to eject nanoparticles from liquids by inducing supercavitation through plasmonic heating, overcoming capillary forces for applications in separation and nanomaterials.

Contribution

The study demonstrates a new technique combining optical forces and supercavitation to efficiently remove nanoparticles from liquids, a process difficult with traditional methods.

Findings

Laser excitation at SPR can eject NPs from liquid.

Supercavitation eliminates capillary forces on NPs.

Method enables NP deposition on solid surfaces.

Abstract

The ability to separate miniscule solid particles (e.g., nanoparticles, NPs) from liquid is important to a wide range of applications, such as water purification, material deposition, and biomedical engineering. Such separation is usually achieved by displacing liquid via filtration or distillation. However, directly moving small particles out of liquid is difficult, especially when their sizes approach the nanometer scale, as the capillary force on the NP at the liquid surface is too large for common body forces (e.g., optical or magnetic) to overcome. Here, we demonstrate the ability to eject metallic NPs out of liquid with a laser excitation at their surface plasmon resonance (SPR) wavelength. The laser applies an optical force on the NPs to drive them toward the liquid surface. In the meantime, the laser can also intensely heat the NP to form a nanobubble encapsulating the NP (i.e., supercavitation), which achieves the liquid-NP separation and thus eliminates the capillary force on the NP at the liquid free surface. We show that such a mechanism can expel NPs out of liquid as observed using a transient scattering experiment, which is further confirmed by molecular dynamics simulations. We also demonstrate depositing the NPs on a solid surface not in contact with the liquid. This study reveals an interesting mechanism to separate NPs from liquid and could potentially benefit separation, nanomaterials and biomedical applications.