Echoes in x-ray speckles track nanometer-scale plastic events in colloidal gels under shear

Rogers, Michael C.; Chen, Kui; Andrzejewski, Lukasz; Narayanan, Suresh; Ramakrishnan, Subramanian; Leheny, Robert L.; Harden, James L.

doi:10.1103/physreve.90.062310

Cited by 48 publications

(31 citation statements)

References 54 publications

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“…There is increasing evidence to suggest that the microscopic mechanism of plastic deformation is a local rearrangement of particles involving a change of nearest neighbours (so called shear transformation zones), which results in an Eshelby-like elastic field 2 3 4 5 . However, it was recently shown that these rearrangements can be repetitive or irreversible depending on the strain amplitude 6 7 8 9 10 11 12 13 14 15 16 17 18 (a similar phenomenon has been observed in the shearing of colloidal suspensions, granular systems, dislocations and super-conducting vortices 19 20 21 22 23 24 25 26 27 28 and in the compaction of granular matter 29 ).…”

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confidence: 80%

Reversibility and criticality in amorphous solids

et al. 2015

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The physical processes governing the onset of yield, where a material changes its shape permanently under external deformation, are not yet understood for amorphous solids that are intrinsically disordered. Here, using molecular dynamics simulations and mean-field theory, we show that at a critical strain amplitude the sizes of clusters of atoms undergoing cooperative rearrangements of displacements (avalanches) diverges. We compare this non-equilibrium critical behaviour to the prevailing concept of a ‘front depinning' transition that has been used to describe steady-state avalanche behaviour in different materials. We explain why a depinning-like process can result in a transition from periodic to chaotic behaviour and why chaotic motion is not possible in pinned systems. These findings suggest that, at least for highly jammed amorphous systems, the irreversibility transition may be a side effect of depinning that occurs in systems where the disorder is not quenched.

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confidence: 80%

Reversibility and criticality in amorphous solids

et al. 2015

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“…At sufficiently high strains (γ 0 > 0.01-0.02), crystal clusters begin to break up and/or become aligned by the shear flow as stress decays (I 3 / 1 keeps increasing or drops). The prevalence of a double-arc shape in I 3 / 1 in some samples might be attributed to two separate yielding processes, as observed in some concentrated colloidal gel or shear instabilities (Wilhelm et al 1999;Rogers et al 2014). To describe the evolution of I 3/1 , we used a descriptive function proposed by Wilhelm et al (2000).…”

Section: Nonlinear Viscoelasticitymentioning

confidence: 99%

Rheological characterization of triglyceride shortenings

Macias‐Rodriguez

Marangoni

2016

Rheol Acta

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The rheological properties of shortenings with similar physicochemical characteristics but diverse functionality were investigated under small and large oscillatory shear. Particular attention was drawn to the mechanical behavior of roll-in shortenings, characterized for resisting work softening and forming continuous fat thin films during dough lamination and sheeting. All shortenings displayed low-frequency dependence, reminiscent of viscoelastic solids where the storage modulus is higher than the loss modulus, and displayed a comparable linear envelope, encompassing relatively small shear strains, such as those encountered in other fat systems. Linear elastic moduli and yield stress, previously used to designate roll-in functionality, remained unremarkable. In contrast, nonlinear viscoelastic behavior of roll-in shortenings differed considerably from all-purpose commercial shortenings. Lissajous-Bowditch curves suggested less local intracycle strain stiffening and less average intercycle strain softening for roll-in shortenings than other shortenings. Likewise, their Fourier spectra indicated a gradual evolution of the third harmonic into the nonlinear regime characterized by higher slopes. The third and fifth harmonics grew monotonically, and the third overtone leveled off and showed no stress decays unlike other samples, suggesting a marked ability of roll-in shortenings to withstand deformation at high stresses. Conversely, the dissipative energy scaled in a similar fashion for all shortenings. Moreover, roll-in shortenings displayed enhanced thixotropic behavior supported by lower power law indexes and prompt structural rebuilding after steady shear cessation. Overall, these rheological signatures facilitated the differentiation among the utilization of shortenings and correlated well with the functionality of roll-in shortenings.

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“…Whereas γ × is frequently quoted as "the" yielding point in the literature, a stress overshoot also serves to identify yielding in shear-start experiments [25]. A stress overshoot is reported in some oscillatory shear experiments [19], but is absent in others [12,13]. A possible explanation is that experiments are typically performed at somewhat larger frequencies, where additional contributions to the shear stress (lubrication forces, hydrodynamic effects) might hide this behaviour.…”

Section: Smooth Crossover In Macroscopic Rheologymentioning

confidence: 99%

Macroscopic yielding in jammed solids is accompanied by a nonequilibrium first-order transition in particle trajectories

2016

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We use computer simulations to analyse the yielding transition during large-amplitude oscillatory shear of a simple model for soft jammed solids. Simultaneous analysis of global mechanical response and particle-scale motion demonstrates that macroscopic yielding, revealed by a smooth crossover in mechanical properties, is accompanied by a sudden change in the particle dynamics, which evolves from non-diffusive motion to irreversible diffusion as the amplitude of the shear is increased. We provide numerical evidence that this sharp change corresponds to a non-equilibrium first-order dynamic phase transition, thus establishing the existence of a well-defined microscopic dynamic signature of the yielding transition in amorphous materials in oscillatory shear.

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Echoes in x-ray speckles track nanometer-scale plastic events in colloidal gels under shear

Cited by 48 publications

References 54 publications

Reversibility and criticality in amorphous solids

Reversibility and criticality in amorphous solids

Rheological characterization of triglyceride shortenings

Macroscopic yielding in jammed solids is accompanied by a nonequilibrium first-order transition in particle trajectories

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