Light Induced Surface Tension Gradients for Hierarchical Assembly of Particles from Liquid Metals

TL;DR

This paper demonstrates that light-induced Marangoni flows in liquid gallium, driven by Laguerre-Gaussian lasers, can precisely assemble particles into ordered ring structures, overcoming Brownian motion in nanofabrication.

Contribution

It introduces a novel method using non-Gaussian laser-induced surface tension gradients to control particle assembly in liquid metals, enabling reconfigurable and high-fidelity structures.

Findings

Light-induced Marangoni flow effectively overcomes Brownian forces.

Laser parameters can tune the assembly structure and fluid dynamics.

Ordered ring-shaped assemblies of particles were achieved with high fidelity.

Abstract

Achieving control over the motion of dissolved particles in liquid metals is of importance for the meticulous realization of hierarchical particle assemblies in a variety of nanofabrication processes. Brownian forces can impede the motion of such particles, impacting the degree of perfection that can be realized in assembled structures. Here we show that light induced Marangoni flow in liquid metals (i.e., liquid-gallium) with Laguerre-gaussian (LG) lasers as heating sources, is an effective approach to overcome Brownian forces on particles, giving rise to predictable assemblies with high degree of order. We show that by carefully engineering surface tension gradients in liquid-gallium using non-gaussian LG lasers, the Marangoni and convective flow that develops in the fluid drives the trajectory of randomly dispersed particles to assemble into 100 um wide ring-shaped particle assemblies. Careful control over the parameters of the LG laser (i.e., laser mode, spot size, and intensity of the electric field) can tune the temperature and fluid dynamics of the liquid-gallium as well as the balance of forces on the particle. This in turn can tune the structure of the ring-shaped particle assembly with a high degree of fidelity. The use of light to control the motion of particles in liquid metals represents a tunable and rapidly reconfigurable approach to spatially design surface tension gradients in fluids for more complex assembly of particles and small-scale solutes. This work can be extended to a variety of liquid-metals, complementary to what has been realized in particle assembly out of ferrofluids using magnetic fields.