AI Article Synopsis
- Active materials can have their bulk properties manipulated by the behavior of their tiny components, which is intriguing for material science.
- Researchers combined microscopy and rheology techniques to study three-dimensional active materials made from microtubules, focusing on how their internal dynamics affect overall movement.
- The study found that viscosity changes unpredictably based on the balance between internal activity and external forces, leading to a successful two-state model that explains the solid and fluid characteristics of these materials.
Article Abstract
An enticing feature of active materials is the possibility of controlling macroscale rheological properties through the activity of the microscopic constituents. Using a unique combination of microscopy and rheology we study three dimensional microtubule-based active materials whose autonomous flows are powered by a continually rearranging connected network. We quantify the relationship between the microscopic dynamics and the bulk mechanical properties of these nonequilibrium networks. Experiments reveal a surprising nonmonotonic viscosity that strongly depends on the relative magnitude of the rate of internally generated activity and the externally applied shear. A simple two-state mechanical model that accounts for both the solidlike and yielded fluidlike elements of the network accurately describes the rheological measurements.
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| http://dx.doi.org/10.1103/PhysRevLett.125.178003 | DOI Listing |
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