Multiple dynamic regimes in concentrated microgel systems

TL;DR

This study explores how dynamical heterogeneities in concentrated microgel systems evolve with packing fraction, revealing two distinct transitions: a fluid-solid transition and a stress-driven squeezed state transition, affecting spatial correlations and mechanical properties.

Contribution

It provides the first evidence of a qualitative change in dynamical heterogeneity from thermal to stress-driven dynamics in microgel systems.

Findings

Spatial correlation length peaks at the fluid-solid transition

Large zones of differing dynamical activity develop beyond the second transition

Frequency-dependent moduli become more coupled indicating stress influence

Abstract

We investigate dynamical heterogeneities in the collective relaxation of a concentrated microgel system, for which the packing fraction can be conveniently varied by changing the temperature. The packing fraction dependent mechanical properties are characterised by a fluid-solid transition, where the system properties switch from a viscous to an elastic low-frequency behaviour. Approaching this transition from below, we find that the range of spatial correlations in the dynamics increases. Beyond this transition, the spatial correlation range reaches a maximum, extending over the entire observable system size of approximately 5 mm. Increasing the packing fraction even further leads to a second transition, which is characterised by the development of large zones of lower and higher dynamical activity that are well separated from each other; the range of correlation decreases at this point. This striking non-monotonic dependence of the spatial correlation length on volume fraction is reminiscent of the behaviour recently observed at the jamming/rigidity transition in granular systems (Lechenault et al. 2008). We identify this second transition as the transition to 'squeezed' states, where the constituents of the system start to exert direct contact forces on each other, such that the dynamics becomes increasingly determined by imbalanced stresses. Evidence of this transition is also found in the frequency dependence of the storage and loss moduli, which become increasingly coupled as direct friction between the particles starts to contribute to the dissipative losses within the system. To our knowledge, our data provide the first observation of a qualitative change in dynamical heterogeneity as the dynamics switch from purely thermally-driven to stress-driven.