Linking Particle Dynamics to Local Connectivity in Colloidal Gels

Doorn, Jan Maarten van; Bronkhorst, Jochem; Higler, Ruben; Laar, Ties van de; Sprakel, Joris

doi:10.1103/physrevlett.118.188001

Cited by 31 publications

(34 citation statements)

References 28 publications

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“…At effective interparticle attractions of many k B T , the thermal energy, detailed balance in the particle attachment and detachment process is broken, and the system falls out of equilibrium; in this case, a description based on an underlying equilibrium phase diagram may no longer apply. This is demonstrated by a recent experimental study on the intermittent dynamics of colloidal gels [17] revealing a marked asymmetry in the cooperative bonding and de-bonding processes. This regime, which is most relevant for biological network formation, is often modelled by cluster kinetic equations, but there is no theory that describes the formation of these out-of-equilibrium structures and is able to explain or predict, from first-principles, the fractal dimension of the growing clusters, and its relation to the cluster mass distribution.…”

Section: Introductionmentioning

confidence: 80%

Nonequilibrium continuous phase transition in colloidal gelation with short-range attraction

et al. 2020

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The arrest of attractive particles into out-of-equilibrium structures known as gelation is central to biophysics, material science and food and cosmetic applications, but a complete understanding is lacking. In particular for intermediate particle density and attraction, the structure formation process remains unclear. Here, we show that the gelation of short-range attractive particles is governed by a nonequilibrium percolation process. We combine experiments on critical Casimir colloidal suspensions, simulations, and analytic modelling with a master kinetic equation to show that cluster sizes and correlation lengths diverge with exponents ∼ 1.6 and 0.8, respectively, consistent with percolation theory, while detailed balance in the particle attachment and detachment processes is broken. Cluster masses exhibit power-law distributions with exponents −3/2 and −5/2 before and after percolation, as predicted by solutions to the master kinetic equation. These results revealing a nonequilibrium continuous phase transition unify the structural arrest and yielding into related frameworks.

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Section: Introductionmentioning

confidence: 80%

Nonequilibrium continuous phase transition in colloidal gelation with short-range attraction

et al. 2020

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“…Yet, the solid regime is of wide interest, not only as its complete description might provide keys for understanding or predicting the solid-liquid transition, but also because of the analogy of these systems with amorphous materials such as metals and glasses or plastic materials [7] and the research on the physical origin of plasticity. It was in particular shown, generally by means of simulations, that plastic deformation manifests as local rearrangements exhibiting a broad distribution of sizes and shapes [25][26], non-affine displacements [27], and connectivity changes between particles [28] that lead to a redistribution of elastic stresses in the system [29]. Furthermore, the collective behavior of these reorganizations includes spontaneous strain localization, intermittent dynamics, power-law distributed avalanches [30] and spatial cooperativity [31].…”

Section: Introductionmentioning

confidence: 99%

Elastoplastic behavior of yield stress fluids

2019

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By means of the incremental elastic modulus for small deformations superimposed on creep and subsequent recovery tests, we follow the structural state of various soft-jammed systems (yield stress fluids) in their solid regime. We demonstrate that the solid state of the material is associated with a persistent elastic network of constant elastic modulus up to yielding (solid-liquid transition), while progressively more additional elastoplastic elements are involved. The main features of these elastoplastic elements, i.e. increase of both the plastic and the elastic deformation components with the square of the shear stress, reveal the fundamental characteristics of a simple generic model (independent of material structure) describing the different components of the mechanical behavior of such systems in their solid regime.

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“…However, ensemble averaging may mask the effect of local structures on the dynamics of individual particles in the mixture. 24 To further investigate this, we examine the relationship between local connectivity, that is, Z and individual particle dynamics for samples with very similar ⟨Δ r 2 ⟩ for these three different polymers; specifically, the samples labeled with closed symbols in Figure 2 . We determine the value of ⟨Δ r 2 ⟩ ( Z , τ) at lag time τ = 200 s for all three samples and show this as a function of Z , measured in the first frame for each time period τ, as seen in Figure 3 .…”

Section: Resultsmentioning

confidence: 99%

“… 21 , 22 Restructuring these networks due to external or internal stresses is governed by events happening at the individual particle level, as the bonds between the particles are typically weak; a relation between local connectivity and thermally activated dynamics at the individual particle level has been reported recently for a depletion-induced colloidal gel. 23 , 24 …”

Section: Introductionmentioning

confidence: 99%

Particle Dynamics in Colloid–Polymer Mixtures with Different Polymer Architectures

Higler

Kodger

et al. 2020

ACS Appl. Mater. Interfaces

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Nonadsorbing polymers are widely used as thickening agents for colloids. A quantitative description of the structure and dynamics of such colloid–polymer mixtures is crucial to reveal the mechanisms accounting for the desired mechanical properties. We use confocal microscopy to study colloids with three types of commonly used polymers with different architectures: linear, subgranular cross-linked, and branched microgels. All three thickeners give rise to heterogeneous colloidal dynamics, characterized by non-Gaussian displacement distributions. However, while the ensemble-averaged particle dynamics in these materials are very similar, the underlying individual particle dynamics are not. Linear polymers give rise to depletion attraction and the formation of colloidal gels, in which the majority of particles are immobilized, while a few weakly bound particles have much higher mobility. By contrast, the branched and cross-linked polymers thicken the continuous phase of the colloid, squeezing the particles into dense pockets, where the mobility is reduced and requires more cooperative rearrangements.

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Linking Particle Dynamics to Local Connectivity in Colloidal Gels

Cited by 31 publications

References 28 publications

Nonequilibrium continuous phase transition in colloidal gelation with short-range attraction

Nonequilibrium continuous phase transition in colloidal gelation with short-range attraction

Elastoplastic behavior of yield stress fluids

Particle Dynamics in Colloid–Polymer Mixtures with Different Polymer Architectures

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