Active rheology of soft solids performed with acoustical tweezers

TL;DR

This paper demonstrates the use of acoustical tweezers to manipulate microbubbles and measure local shear modulus in soft hydrogels, providing a new active rheology method that aligns well with traditional rheometry.

Contribution

It introduces a novel application of acoustical tweezers for local mechanical property measurement in soft materials, combining optical detection and elastic modeling.

Findings

Microbubbles can be stably trapped and manipulated off-axis.

The shear modulus measured locally agrees with bulk rheometry.

Acoustical tweezers enable characterization of complex soft materials.

Abstract

Single-beam acoustical tweezers are used to manipulate individual microbubbles and provide quantitative measurements of the local shear modulus of soft hydrogels. The microbubbles are directly generated by electrolysis of the hydrogel and their displacement is detected using optical microscopy in the focal plane of a focused vortex beam. Microbubbles displaced off-axis can be pulled by a restoring radial force component that forms a stable two-dimensional trap. We also observe an off-axis tangential microbubble motion that is due to the transfer of the beam's angular momentum flux. A simple elastic model for the hydrogel deformation combined with radiation force calculations finally provide local values of the medium's shear modulus, which are found to be in good agreement with standard bulk measurements performed with a rheometer. Our results suggest that acoustical tweezers are relevant tools to characterize the local mechanical properties of complex soft materials opening new opportunities in the field of active rheology.