Colloidal gels tuned by oscillatory shear

Moghimi, Esmaeel; Jacob, Alan R.; Koumakis, Nick; Petekidis, George

doi:10.1039/c6sm02508k

Cited by 85 publications

(82 citation statements)

References 62 publications

(113 reference statements)

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“…This suggests that the applied deformation leads to accelerated aging and coarsening of the gel strand, driving it gradually into a more favorable state by forming more inter-particle bonds. 25,40 A similar strain-induced increase of the number of interparticle bonds has been seen in computer simulations 41 and in experiments 24 on colloidal gel networks. We note that the strain-induced increase in the number of bonds is more pronounced and continues for a longer period as the gel strands get thicker (see also ESI, † Fig.…”

Section: Soft Matter Papersupporting

confidence: 57%

“…[15][16][17] The main control parameters that determine the structure of a colloidal gel are the magnitude of the attraction strength between the particles, [18][19][20][21][22] the particle volume fraction, 18,21,22 and the shear history of the gel. [23][24][25]44 In the limit of very strong attraction and very low volume fraction, irreversible aggregation leads to the formation of dilute, diffusion-limited fractal gels. 18 In this regime, the mechanics and dynamics of the gel can be described using scaling approaches or by simulation models based on percolating networks of gel strands that ignore the internal structure of the strands.…”

Section: Introductionmentioning

confidence: 99%

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Plasticity in colloidal gel strands

et al. 2019

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Section: Soft Matter Papersupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

Plasticity in colloidal gel strands

et al. 2019

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“…The open symbols show the evolution of the storage moduli parallel to the previous flow direction, indicated with the subscript h. Such time evolution after cessation of flow of what are typically called "the" moduli was reported for many types of colloidal gels, with an increase of orders of magnitude in storage modulus [37,[53][54][55][56][57]. In comparison, the loss moduli are far less affected by flow.…”

Section: Superposition Rheology Of Gelsmentioning

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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“…Either the gel accumulates damage under shear until it is irreversibly destroyed (gel collapse), or the gel recovers after flow cessation, and eventually re-forms a percolated network, given a sufficiently long period of rest. These two types of behavior allow to us to distinguish between colloidal gels that experience an irreversible yielding transition [16][17][18][19], and colloidal gels that can be rejuvenated due to the shear-reversible nature of the interparticle attractive interactions such as van der Waals or depletion interactions [20][21][22][23]. The re- * Corresponding author: ajhart@mit.edu covery step of the latter category of gels has been termed "rheological aging" and the kinetics of such phenomena are a complex function of the volume fraction, the nature of the interparticle interactions and the shear history [24][25][26][27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Shear melting and recovery of crosslinkable cellulose nanocrystal–polymer gels

et al. 2019

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Cellulose nanocrystals (CNC) are naturally-derived nanostructures of growing importance for the production of composites having attractive mechanical properties, and offer improved sustainability over purely petroleum-based alternatives. Fabrication of CNC composites typically involves extrusion of CNC suspensions and gels in a variety of solvents, in the presence of additives such as polymers and curing agents. However, most studies so far have focused on aqueous CNC gels, yet the behavior of CNC-polymer gels in organic solvents is important to their wider processability. Here, we study the rheological behavior of composite polymer-CNC gels in dimethylformamide, which include additives for both UV and thermal crosslinking. Using rheometry coupled with in-situ infrared spectroscopy, we show that under external shear, CNC-polymer gels display progressive and irreversible failure of the hydrogen bond network that is responsible for their pronounced elastic properties. In the absence of cross-linking additives, the polymer-CNC gels show negligible recovery upon cessation of flow, while the presence of additives allows the gels to recover via van der Waals interactions. By exploring a broad range of shear history and CNC concentrations, we construct master curves for the temporal evolution of the viscoelastic properties of the polymer-CNC gels, illustrating universality of the observed dynamics with respect to gel composition and flow conditions. We therefore find that polymer-CNC composite gels display a number of the distinctive features of colloidal glasses and, strikingly, that their response to the flow conditions encountered during processing can be tuned by chemical additives. These findings have implications for processing of dense CNC-polymer composites in solvent casting, 3D printing, and other manufacturing techniques. arXiv:1901.04373v1 [cond-mat.soft]

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Colloidal gels tuned by oscillatory shear

Cited by 85 publications

References 62 publications

Plasticity in colloidal gel strands

Plasticity in colloidal gel strands

Superposition rheology and anisotropy in rheological properties of sheared colloidal gels

Shear melting and recovery of crosslinkable cellulose nanocrystal–polymer gels

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