Revealing the frictional transition in shear-thickening suspensions

Clavaud, Cécile; Bérut, Antoine; Metzger, Bloen; Forterre, Yoël

doi:10.1073/pnas.1703926114

Cited by 142 publications

(134 citation statements)

References 47 publications

(66 reference statements)

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“…This jamming at lower values of ϕ in frictional systems is the result of the breakdown of lubrication and the onset of frictional contacts with the appearance of force chains as described in section 3.1 [Fernandez et al, 2013;Ness and Sun, 2016b;Wyart and Cates, 2014]. It is now understood that this process is fundamental to the rheology of hydrogranular flow and signals the onset of the so-called "boundary lubrication" frictional regime distinct from the "hydrodynamic" regime, where lubrication films are intact and particle friction plays almost no role [Bi et al, 2011;Clavaud et al, 2017;Fernandez et al, 2013;Grob et al, 2014;Mari et al, 2014]. A hydrogranular system in the hydrodynamic regime will jam at a value of ϕ = ϕ RCP , like that of frictionless systems.…”

Section: 1002/2017jb014218mentioning

confidence: 99%

“…At large values of s, the so-called hydrodynamic regime, a fluid layer separates the two particle surfaces and so the bulk coefficient of friction depends on the value of s, not just the dry value of the particle-particle friction coefficient. However, when s ≪ 1, the system is in a contact frictional regime, the first normal stress difference is nonzero, and the bulk friction depends weakly on s and is described by the dry friction coefficient [Clavaud et al, 2017;Fernandez et al, 2013]. For geological applications we consider a roughness scale of δ rough = 1 μm.…”

Section: 1002/2017jb014218mentioning

confidence: 99%

“…The Sommerfeld number (39) provides the criteria for this transition between boundary and hydrodynamic states of lubrication and explains why there are two states of jamming possible in a hydrogranular systems: (1) In the hydrodynamic lubrication case, jamming occurs closer to a single value of ϕ and is not sensitive to values of particle friction coefficient, and (2) a so-called shear-jamming regime, associated with the onset of frictional contacts, the emergence of a force chain network, and a value of ϕ pc that is not single-valued and depends explicitly on the value of the particle-particle friction coefficient. The emergence of frictional behavior is now understood as contributing to continuous (suspension viscosity is proportional to shear rate) and producing discontinuous (large discontinuous jumps in suspension viscosity as a function of shear rate) shear thickening as well [Clavaud et al, 2017;Lin et al, 2015;Majumdar et al, 2017;Mari et al, 2014;Ness and Sun, 2015, 2016a, 2016bPeters et al, 2016;Royer et al, 2016;Wyart and Cates, 2014].…”

Section: 1002/2017jb014218mentioning

confidence: 99%

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On the kinematics and dynamics of crystal‐rich systems

2017

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Partially molten rocks, often called a mush, are examples of a hydrogranular mixture where the dynamics are controlled by both fluid and crystal‐crystal interactions. An obstacle to progress in understanding high‐temperature hydrogranular systems has been the lack of adequate levels of description of microphysical processes. Here we rationalize the hydrogranular kinematic and dynamic states by applying the concept of particle (crystal) force chains. We exemplify this with discrete‐element computational fluid dynamic simulations of the intrusion of a basaltic melt into an olivine‐basalt mush, where crystal‐scale force chains, crystal transport, and melt mixing are resolved. To describe the microscale kinematics of the system, we introduce the coordination number and the fabric tensors of particle contacts and forces. We quantify the changing contact and force fabric anisotropy, coaxiality, and the connectedness of the mush, under dynamic conditions. To describe the dynamics, particle and fluid characteristic response times are derived. These are used to define local and bulk Stokes numbers, and viscous and inertia numbers, which quantify the multiphase coupling under crystal‐rich conditions. We employ the Sommerfeld number, which describes the importance of crystal‐melt lubrication, with a viscous number to illustrate the dynamic regimes of crystal‐rich magmas. We show that the notion of mechanical “lock up” is not uniquely identified with a particular crystal volume fraction and that distinct mechanical behaviors can emerge simultaneously within a crystal‐rich system. We also posit that this framework describes magmatic fabrics and processes which “unlock” a crystal mush prior to eruption or mixing.

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Section: 1002/2017jb014218mentioning

confidence: 99%

Section: 1002/2017jb014218mentioning

confidence: 99%

Section: 1002/2017jb014218mentioning

confidence: 99%

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On the kinematics and dynamics of crystal‐rich systems

2017

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“…While the shear-induced growth of particle clusters, referred to as "hydroclusters," has long been invoked to explain shear thickening, especially in Brownian suspensions of small colloidal particles [11,12], it was recently recognized that shear thickening involves solid friction activated through shear-induced compressive stresses, at least for non-Brownian particles [13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Uncovering Instabilities in the Spatiotemporal Dynamics of a Shear-Thickening Cornstarch Suspension

2018

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Recent theories predict that discontinuous shear thickening (DST) involves an instability, the nature of which remains elusive. Here, we explore unsteady dynamics in a dense cornstarch suspension by coupling long rheological measurements under constant shear stresses to ultrasound imaging. We demonstrate that unsteadiness in DST results from localized bands that travel along the vorticity direction with a specific signature on the global shear rate response. These propagating events coexist with quiescent phases for stresses slightly above DST onset, resulting in intermittent, turbulentlike dynamics. Deeper into DST, events proliferate, leading to simpler, Gaussian dynamics. We interpret our results in terms of unstable vorticity bands as inferred from recent model and numerical simulations.

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“…The most recent success in the area has been the reproduction of the phenomenon of discontinuous shear thickening, the abrupt increase in the steady shear viscosity of a suspension when the shear rate is increased beyond some critical rate. It is now widely accepted that a key ingredient of the phenomenon is 'stress-induced friction' (Mari et al 2014;Wyart & Cates 2014), and this has been confirmed by experiment (Lin et al 2015;Clavaud et al 2017).…”

Section: Introductionmentioning

confidence: 88%

‘Shear thickening’ in non-shear flows: the effect of microstructure

Wilson

2017

J. Fluid Mech.

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The bizarre behaviour of a cornstarch suspension (sometimes called oobleck) is well known to all of us who have led public engagement events. At the right solids fraction, it flows smoothly at slow speeds, but can be shattered with a quick spoon movement; if you prepare a large enough sample, you can run across the surface (but if you stand still, you will sink). In rheology circles this phenomenon is known as shear thickening, though the flows described above are not necessarily shear-dominated. In recent years there has been a proliferation of research on the mechanism behind true shear thickening, using both experiments and numerical simulations of shear flows. The understanding of the underlying mechanism is improving markedly. But the paper 'Microstructure and thickening of dense suspensions under extensional and shear flows' (Seto, Giusteri & Martinello, J. Fluid Mech., vol. 825, 2017, R3) is the first to consider more general flows. We have, for the first time, simulations of thickening in extensional flows, which are a far better description of oobleck with a runner on top -and can begin to quantify the difference between the idealised shear thickening and the extension thickening that happens in practice.

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Revealing the frictional transition in shear-thickening suspensions

Cited by 142 publications

References 47 publications

On the kinematics and dynamics of crystal‐rich systems

On the kinematics and dynamics of crystal‐rich systems

Uncovering Instabilities in the Spatiotemporal Dynamics of a Shear-Thickening Cornstarch Suspension

‘Shear thickening’ in non-shear flows: the effect of microstructure

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