Internal dynamics and activated processes in soft-glassy materials

Benzi, Roberto; Sbragaglia, Mauro; Scagliarini, Andrea; Perlekar, Prasad; Bernaschi, Massimo; Succi, Sauro; Toschi, Federico

doi:10.1039/c4sm02341b

Cited by 22 publications

(29 citation statements)

References 45 publications

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“…The diffusive growth of local stress fluctuations with time has been confirmed by molecular dynamics simulations of model glasses at least at very low shear rates, where Puosi et al (2015) have reported that (ξ pl (t + ∆t) − ξ pl (t)) 2 ∝ ∆t. One should however mention that in this context the observation of stochastic resonance induced by mechanical noise in lattice-Boltmann simulations of emulsions is puzzling (Benzi et al, 2015). The question of the mechanical noise has also sparked intense debate on the experimental side.…”

Section: Mechanical Noise V Thermal Fluctuationsmentioning

confidence: 99%

Deformation and flow of amorphous solids: Insights from elastoplastic models

et al. 2018

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CONTENTSFrequently used notations 3 FIG. 1 Overview of amorphous solids. From left to right, top row : cellular phone case made of metallic glass (1); toothpaste (2); mayonnaise (3); coffee foam (4); soya beans (5). Second row : a transmission electron microscopy (TEM) image of a fractured bulk metallic glass (Cu50Zr45Ti5) by X. Tong et. al (Shanghai University, China); TEM image of blend (PLLA/PS) nanoparticles obtained by miniemulsion polymerization, from L. Becker Peres et al. (UFSC, Brazil); emulsion of water droplets in silicon oil observed with an optical microscope by N. Bremond (ESPCI Paris); a soap foam filmed in the lab by M. van Hecke (Leiden University, Netherlands); thin nylon cylinders of different diameters pictured with a camera, from T. Miller et al. (University of Sydney, Australia). The white scale bars are approximate. Just below, a chart of different amorphous materials, classified by the size and the damping regime of their elementary particles. At the bottom: some popular modeling approaches, arranged according to the length scales of the materials for which they were originally developed. STZ stands for the shear transformation zone theory of Langer (2008), and SGR for the soft glassy rheology theory of Sollich et al. (1997).

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Section: Mechanical Noise V Thermal Fluctuationsmentioning

confidence: 99%

Deformation and flow of amorphous solids: Insights from elastoplastic models

et al. 2018

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“…The simulations use a model based on Lattice Boltzmann equations (LBE) for complex fluids [5], which are discussed in detail in [1,3,4]. The model simulates two repelling fluids, say A and B, with the same density.…”

Section: Numerical Simulationsmentioning

confidence: 99%

On interevent time distributions of avalanche dynamics

Kumar

Korkolis

Benzi

et al. 2020

Sci Rep

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Physical systems characterized by stick-slip dynamics often display avalanches. Regardless of the diversity of their microscopic structure, these systems are governed by a power-law distribution of avalanche size and duration. Here we focus on the interevent times between avalanches and show that, unlike their distributions of size and duration, the interevent time distributions are able to distinguish different mechanical states of the system, characterized by different volume fractions or confining pressures. We use experiments on granular systems and numerical simulations of emulsions to show that systems having the same probability distribution for avalanche size and duration can have different interevent time distributions. Remarkably, for large packing ratios, these interevent time distributions look similar to those for earthquakes and are indirect evidence of large space-time correlations in the system. Our results therefore indicate that interevent time statistics are more informative to characterize the dynamics of avalanches. arXiv:1906.09897v1 [cond-mat.soft]

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“…The above definition of F c k is to mimic the spatially complex (non-monotonic) interactions among molecules within each species. For example, the interplay between the competing interactions can give rise to a rich density-field configuration, which has proved fairly successful in reproducing many features of soft flowing systems, such as structural frustration, aging, elastoplastic rheology, in confined and unbounded flows 9,25,48,49 . In addition, it has been shown that by appropriately tuning the strengths of the two interactions, a positive disjoining pressure Π , which emerges as a repulsive force per unit area between opposing interfaces, can be obtained at sufficiently low film thickness 48 .…”

Section: Model Description and Validationmentioning

confidence: 99%

Discrete fluidization of dense monodisperse emulsions in neutral wetting microchannels

et al. 2020

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The rheology of pressure-driven flows of two-dimensional dense monodisperse emulsions in neutral wetting microchannels is investigated by means of mesoscopic lattice simulations, capable of handling large collections of droplets, in the order of several hundreds. The simulations reveal that the fluidization of the emulsion proceeds through a sequence of discrete steps, characterized by yielding events whereby layers of droplets start rolling over each other, thus leading to sudden drops of the relative effective viscosity. It is shown that such discrete fluidization is robust against loss of confinement, namely it persists also in the regime of small ratios of the droplet diameter over the microchannel width. We also develop a simple phenomenological model which predicts a linear relation between the relative effective viscosity of the emulsion and the product of the confinement parameter (global size of the device over droplet radius) and the viscosity ratio between the disperse and continuous phases. The model shows excellent agreement with the numerical simulations. The present work offers new insights to enable the design of microfluidic scaffolds for tissue engineering applications and paves the way to detailed rheological studies of soft-glassy materials in complex geometries.The shear rheology of a wide class of SGMs 10-12 can be described by the Herschel-Bulkley relation 13 between the applied stress σ and the responsive shear rateγ,In Eq. (1), σ Y is the yield stress, below which the material J o u r n a l N a me , [ y e a r ] , [ v o l . ] , 1-8 | 1 arXiv:1910.01978v2 [cond-mat.soft] 30 Nov 2019 2 | 1-8 J o u r n a l N a me , [ y e a r ] , [ v o l . ] ,

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Internal dynamics and activated processes in soft-glassy materials

Cited by 22 publications

References 45 publications

Deformation and flow of amorphous solids: Insights from elastoplastic models

Deformation and flow of amorphous solids: Insights from elastoplastic models

On interevent time distributions of avalanche dynamics

Discrete fluidization of dense monodisperse emulsions in neutral wetting microchannels

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