Theory and simulation of AC electroosmotic suppression of acoustic streaming

TL;DR

This paper explores how combining ultrasound acoustics with AC electroosmosis can significantly suppress acoustic streaming in resonating acoustofluidic devices, enhancing nanoparticle handling capabilities.

Contribution

It provides a theoretical and simulation-based analysis of electroosmotic suppression of acoustic streaming, including an analytical expression for slip velocity and nonlinear regime modeling.

Findings

Electroosmotic suppression reduces streaming by two orders of magnitude.

A theoretical framework for electrokinetic potential at the fluid-solid interface.

Simulation results demonstrate effective streaming suppression in device models.

Abstract

Acoustic handling of nanoparticles in resonating acoustofluidic devices is often impeded by the presence of acoustic streaming. For micrometer-sized acoustic chambers, this acoustic streaming is typically driven from the fluid-solid interface by viscous shear-stresses generated by the acoustic actuation. AC electroosmosis is another boundary-driven streaming phenomena routinely used in microfluidic devices for handling of particle suspensions in electrolytes. Here, we study how streaming can be suppressed by combining ultrasound acoustics and AC electroosmosis. Based on a theoretical analysis of the electrokinetic problem, we are able to compute numerically a form of the electrical potential at the fluid-solid interface, which is suitable for suppressing a typical acoustic streaming pattern associated with a standing acoustic half-wave. In the linear regime, we even derive an analytical expression for the electroosmotic slip velocity at the fluid-solid interface, and use this as a guiding principle for developing models in the experimentally more relevant nonlinear regime that occurs at elevated driving voltages. We present simulation results for an acoustofluidic device, showing how implementing a suitable AC electroosmosis results in a suppression of the resulting streaming in the bulk of the device by two orders of magnitude.