Elasticity of Arrested Short-Ranged Attractive Colloids: Homogeneous and Heterogeneous Glasses

Zaccone, Alessio; Wu, Hua; Gado, Emanuela Del

doi:10.1103/physrevlett.103.208301

Cited by 114 publications

(107 citation statements)

References 39 publications

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“…The final arrested plateau value of the elastic modulus, G p , increases dramatically with increasing quench depth by nearly an order of magnitude. 74 For larger values of L c (i.e. 42 This is captured in Fig.…”

Section: Quench-dependence Of the Arrested Statementioning

confidence: 83%

Microdynamics and arrest of coarsening during spinodal decomposition in thermoreversible colloidal gels

2015

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Coarsening and kinetic arrest of colloidal systems undergoing spinodal decomposition (SD) is a conserved motif for forming hierarchical, bicontinuous structures. Although the thermodynamic origins of SD in colloids are widely known, the microstructural processes responsible for its coarsening and associated dynamics en route to arrest remain elusive. To better elucidate the underlying large-scale microdynamical processes, we study a colloidal system with moderate-range attractions which displays characteristic features of arrested SD, and study its dynamics during coarsening through a combination of differential dynamic microscopy and real-space tracking. Using these recently developed imaging techniques, we reveal directly that the coarsening arises from collective dynamics of dense domains, which undergo slow, intermittent, and ballistic motion. These collective motions indicate interfacial effects to be the driving force of coarsening. The nature of the gelation enables control of the arrested length scale of coarsening by the depths of quenching into the spinodal regime, which we demonstrate to provide an effective means to control the elasticity of colloidal gels.

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Section: Quench-dependence Of the Arrested Statementioning

confidence: 83%

Microdynamics and arrest of coarsening during spinodal decomposition in thermoreversible colloidal gels

2015

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“…Various approaches have been proposed to explain a) Author to whom correspondence should be addressed; electronic mail: jan.vermant@mat.ethz.ch these properties, with most theories focusing on the structure at rest. For strong gels, fractal scalings [7,8] and poroelastic models [9] have been proposed linking the elasticity of the gel network to the rigidity of intra-or interfloc links [7,10]. In weaker gels with more of a bicontinuous, disordered morphology, it has been suggested that the elasticity is determined by the localization of particles in the gel, which slows down the Brownian relaxation processes.…”

Section: Introductionmentioning

confidence: 99%

Superposition rheology and anisotropy in rheological properties of sheared colloidal gels

Colombo

Kim

Schweizer

et al. 2017

Journal of Rheology

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Gelling colloidal suspensions represent an important class of soft materials. Their mechanical response is characterized by a solid-to-liquid transition at a given shear stress level. Moreover, they often exhibit a complex time-dependent rheological behavior known as thixotropy. The viscosity changes find their origin in the microstructure, which depends on flow history. Yet, the structural response of colloidal gels to flow differs fundamentally from most complex fluids, where flow induces orientation. Upon yielding, low to intermediate volume fraction gels break down in a spatially anisotropic way. Bonds in the velocity-velocity gradient plane are broken, whereas microstructural features in other planes are less affected. The subsequent flow-induced microstructural anisotropy is characterized by typical butterfly scattering patterns. However, as yet there was no evidence for the pertinence of this anisotropy for the rheological properties of these systems. In the present work, orthogonal superposition rheometry was first used to evaluate how the flow-induced microstructure affects the viscoelastic properties. It was shown to retain significant elasticity in the velocity-vorticity plane, even when the structure liquefied. Further, the shearinduced mechanical anisotropy was measured using two-dimensional small amplitude oscillatory shear, exploiting the fact that for suitable thixotropic samples the recovery after arresting the flow is relatively slow. It was hence possible to measure the anisotropy of the moduli upon cessation of flow. The mechanical anisotropy was shown to be spectacular, with the storage moduli in perpendicular directions differing by as much as 2 orders of magnitude. V C 2017 The Society of Rheology. [http://dx

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“…Indeed, altering the strength and range of the attractions at the origin of colloidal gelation enables tailoring the properties of colloidal dispersions to wider-ranging and challenging applications, from foodstuff and cosmetics to pharmaceutical and chemical products. In the recent years, advances in modeling and simulation [Zaccone et al (2009);Zaccarelli (2007); Del Gado and Kob (2007);a) Author to whom correspondence should be addressed; electronic mail: dvlasso@iesl.forth.gr V C 2014 by The Society of Rheology, Inc. J. Rheol. 58(5), 1441-1462September/October (2014 0148-6055/2014/58(5)/1441/22/$30.00 Puertas et al (2004); Cates et al (2004); Ramakrishan et al (2002); Mao et al (1995)] and the emergence of (hard) colloid-polymer mixtures as an ideal model system for exploring the whole range of colloidal behaviors from dilute gels to dense glasses [Pham et al (2002); Poon (2002)] gave a new boost to the field and triggered new efforts (experimental and modeling/simulations) toward the fundamental understanding of phenomena related to colloidal gelation.…”

Section: Introductionmentioning

confidence: 99%

Depletion gels from dense soft colloids: Rheology and thermoreversible melting

Truzzolillo¹,

Vlassopoulos²,

Munam³

et al. 2014

Journal of Rheology

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SynopsisUpon addition of small nonadsorbing linear polymers, colloidal glasses composed of large hard spheres melt and eventually revitrify into the so-called attractive glass regime. We show that, when replacing the hard spheres by star polymers representing model soft particles, a reentrant gel is formed. This is the result of compression and depletion of the stars due to the action of the osmotic pressure from the linear homopolymers. The viscoelastic properties of the soft dense gel were studied with emphasis on the shear-induced yielding process, which involved localized breaking of elements with a size of the order of the correlation length. Based on these results, a phenomenological attempt was made at describing the universal rheological features of colloid/nonadsorbing polymer mixtures of varying softness. The star gel was found to undergo thermoreversible melting, despite the fact that conventional hard-sphere depletion gels are invariant to heating. This phenomenon is attributed to the hybrid internal microstructure of the stars, akin to a dry-to-wet brush transition, and is characterized by slow kinetics, on the time scale of the osmotic gel formation process. These results may be useful in finding generic features in colloidal gelation, as well as in the molecular design of new soft composite materials. V C 2014 The Society of Rheology. [http://dx

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Elasticity of Arrested Short-Ranged Attractive Colloids: Homogeneous and Heterogeneous Glasses

Cited by 114 publications

References 39 publications

Microdynamics and arrest of coarsening during spinodal decomposition in thermoreversible colloidal gels

Microdynamics and arrest of coarsening during spinodal decomposition in thermoreversible colloidal gels

Superposition rheology and anisotropy in rheological properties of sheared colloidal gels

Depletion gels from dense soft colloids: Rheology and thermoreversible melting

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