Abstract
In quenched disordered out-of-equilibrium many-body colloidal systems, there are important distinctions between the glass transition, which is related to the onset of nonergodicity and loss of low-frequency relaxations caused by crowding, and the jamming transition, which is related to the dramatic increase in elasticity of the system caused by the deformation of constituent objects. For softer repulsive interaction potentials, these two transitions become increasingly smeared together, so measuring a clear distinction between where the glass ends and where jamming begins becomes very difficult or even impossible. Here, we investigate droplet dynamics in concentrated silicone oil-in-water nanoemulsions using light scattering. For zero or low NaCl electrolyte concentrations, interfacial repulsions are soft and longer in range, this transition sets in at lower concentrations, and the glass and the jamming regimes are smeared. However, at higher electrolyte concentrations the interactions are stiffer, and the characteristics of the glass-jamming transition resemble more closely the situation of disordered elastic spheres having sharp interfaces, so the glass and jamming regimes can be distinguished more clearly.
Highlights
Heterodyne diffusing wave spectroscopy (DWS) overlaps with low-coherence dynamic light scattering (LC-DLS) in the desired φ-range that we explore and extends the measurements to very high concentrations
We have chosen relatively small droplets that can be studied by light scattering and that would display a readily measurable plateau shear modulus near and above the glass transition, kBT /R3 > 1Pa. as a consequence of the small droplet size, direct interactions are dominated by electrostatic repulsive double-layer forces over a relatively large range of concentrations, whereas interactions due the interfacial elasticity of the emulsion droplets only play a dominant role deep in the (core-)jammed regime
Summary
The aim of our study is to characterize the internal dynamics and elasticity of disordered uniform nanoemulsions over a range of φ extending below, through, and above both the glass transition and the jamming transition. The aim of our study is to characterize the the internal dynamics and elasticity of disordered uniform colloidal emulsions from the liquid, through the near-glass and full glassy regime corresponding to dynamic arrest, and well into the highly compressed jammed states at even larger φ. We aim to cover an unusually large range of droplet displacements for the arrested states. Icnoolluecrteixvpe edreimcaeynotfs density we aim to probe the latter, q ≥ qm, using both LC-DLS and DWS
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