Optically Driven Gold Nanoparticles Seed Surface Bubble Nucleation in Plasmonic Suspension

TL;DR

This study reveals that optically driven nanoparticles depositing on a surface initiate photothermal bubble formation in plasmonic suspensions, with the process influenced by optical forces and nanoparticle density.

Contribution

It demonstrates that nanoparticle deposition via optical forces causes bubble nucleation, highlighting the roles of optical pulling and pushing, which was previously unclear.

Findings

Nanoparticles move and adhere to surfaces before bubble formation.

Bubble nucleation thresholds depend on surface orientation and optical forces.

A critical nanoparticle density is required for bubble nucleation at given laser power.

Abstract

Photothermal surface bubbles play important roles in a wide range of applications like catalysis, microfluidics and biosensing, but their formation on a transparent substrate immersed in a plasmonic nanoparticle (NP) suspension has an unknown origin. Here, we show that NPs deposited on the substrate by dispersive optical forces are responsible for the nucleation of such photothermal surface bubbles. High-speed videography shows that the surface bubble formation is always preceded by the optically driven NPs moving toward and adhering to the surface. We observe that the thresholds of laser power density to form a surface bubble drastically differ depending on if the surface is forward- or backward-facing the light propagation direction, which cannot be explained by a purely thermal process (e.g., volumetric heating by plasmonic NPs). This can be attributed to different optical power densities needed to enable optical pulling and pushing of NPs in the suspension. Optical pulling requires higher light intensity to excite supercavitation around NPs to enable proper optical configuration. Eventually, these optically deposited NPs work as a surface photothermal heater, seeding the surface bubble nucleation. We also find that there is a critical number density of deposited NPs to nucleate a surface bubble at a given laser power density, and it is nearly the same for both the forward- and the backward-facing surfaces. Our finding reveals interesting physics leading to photothermal surface bubble generation in plasmonic NP suspensions.