A hallmark of concentrated suspensions is non-Newtonian behavior, whereby the viscosity increases dramatically once a characteristic shear rate or stress is exceeded. Such strong shear thickening is thought to originate from a network of frictional particle-particle contact forces, which forms under sufficiently large stress, evolves dynamically, and adapts to changing loads. While there is much evidence from simulations for the emergence of this network during shear thickening, experimental confirmation has been difficult. Here, we use suspensions of piezoelectric nanoparticles and exploit the strong local stress focusing within the network to activate charge generation. This charging can then be detected in the measured ac conductance and serve as a signature of frictional contact formation. The direct link between stress-activated frictional particle interactions and piezoelectric suspension response is further demonstrated by tracking the emergence of structural memory in the contact network under oscillatory shear and by showing how stress-activated friction can drive mechano-transduction of chemical reactions with nonlinear reaction kinetics. Taken together, this makes the ac conductance of piezoelectric suspensions a sensitive in-situ reporter of the micromechanics associated with frictional interactions.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10710073 | PMC |
| http://dx.doi.org/10.1073/pnas.2310088120 | DOI Listing |
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Article Synopsis
- This study uses particle-based simulations to explore how stress-activated constraints affect discontinuous shear thickening (DST) and shear jamming (SJ) in suspensions, particularly focusing on resistance due to rolling friction.
- It finds that rolling friction lowers the volume fraction needed for DST and SJ, aligning with observed behaviors in real-world suspensions that have adhesive surfaces and rough particle shapes.
- Overall, the research highlights that rolling friction significantly alters the frictional force network and contributes to increased viscosity in these materials, making it essential for understanding shear-thickening behavior.
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