Optical rotation of ferrofluid on a horizontal substrate by Marangoni and thermomagnetic forces

TL;DR

This paper demonstrates the first laser-induced optical rotation of ferrofluid on a horizontal substrate, utilizing Marangoni and thermomagnetic forces, advancing non-contact liquid manipulation techniques in microfluidics.

Contribution

It introduces a novel method for rotating ferrofluid on a horizontal surface using laser and magnetic fields, revealing the underlying mechanisms involved.

Findings

Ferrofluid exhibits controllable rotation by laser positioning.

Rotation depends on laser power, position, and magnetic field strength.

Mechanism involves displacement of ferrofluid centers due to combined forces.

Abstract

Light-actuation enables non-contact, precise, and flexible manipulation of liquids in microfluidics and liquid robots. However, it has long been a challenge to achieve optical rotation of liquid on a horizontal substrate because of the weak force of light. Here, we report, for the first time, the laser-induced rotation of macroscopic liquid placed on a horizontal substrate above cylindrical magnets. The investigated ferrofluid exhibits multiple spikes due to the Rosensweig phenomenon on the surface with different strengths of external magnetic field and rotates in a controllable direction by adjusting the laser beam position around ferrofluid spikes. This rotation results from the laser-induced displacement between the ferrofluid gravitational center, magnetic field center, Marangoni force, and non-uniform thermomagnetic force. Movement tracking of the spikes, thermal magnetization, and thermal imaging of ferrofluid were performed to elucidate the mechanism. Additionally, the influence of laser power, laser irradiation position, and magnetic field intensity on laser-induced rotation of ferrofluid are systematically studied. This work demonstrates a novel horizontal rotation of liquid using light and provides a deep understanding of the underlying mechanism and a flexible strategy for manipulating liquid for various optofluidic applications.