Mechanics and structure of carbon black gels under high-power ultrasound

Colloidal gels made of carbon black particles dispersed in light mineral oil are rheo-acoustic materials, i.e., their mechanical and structural properties can be tuned using high-power ultrasound, sound waves with submicrometer amplitude and frequencies larger than 20 kHz. The effects of high-power ultrasound on the carbon black gel are demonstrated using two experiments: rheology coupled to ultrasound to test for the gel mechanical response and a time-resolved ultra-small-angle x-ray scattering experiment (TRUSAXS) coupled to ultrasound to test for structural changes within the gel. We show that high-power ultrasound above a critical amplitude leads to a complex viscoelastic transient response of the gels within a few seconds: a softening of its storage modulus accompanied by a strong overshoot in its loss modulus. Under high-power ultrasound, the gel displays a viscoelastic spectrum with glasslike features and a significant decrease in its yield strain. Those effects are attributed to the formation of intermittent microcracks in the bulk of the gel as evidenced by TRUSAXS. Provided that the shear rate is not large enough to fully fluidize the sample, high-power ultrasound also facilitates the flow of the gel, reducing its yield stress as well as increasing the shear-thinning index, thanks again to the formation of microcracks. (C) 2021 The Society of Rheology.

Automated summary

This study demonstrates the effects of high-power ultrasound on carbon black gels, showing adjustments in both mechanical and structural properties. High-power ultrasound leads to a complex viscoelastic transient response in the gels, with a softening of the storage modulus and a significant increase in the loss modulus. The formation of intermittent microcracks within the gel contributes to these effects, ultimately facilitating gel flow and reducing yield stress.