Dynamics of Surfactant-Driven Fracture of Particle Rafts

Vella, Dominic; Kim, Ho-Young; Aussillous, Pascale; Mahadevan, L.

doi:10.1103/physrevlett.96.178301

Cited by 37 publications

(41 citation statements)

References 13 publications

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“…In addition, prior studies of viscoelastic substrates have focused on substrate breakup or fracture when subjected to stresses [10,11,12,13]. Here, we observe a failure of the gel driven by surface tension.…”

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Instabilities in Droplets Spreading on Gels

et al. 2007

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We report a novel surface-tension driven instability observed for droplets spreading on a compliant substrate. When a droplet is released on the surface of an agar gel, it forms arms/cracks when the ratio of surface tension gradient to gel strength is sufficiently large. We explore a range of gel strengths and droplet surface tensions and find that the onset of the instability and the number of arms depend on the ratio of surface tension to gel strength. However, the arm length grows with an apparently universal law L ∝ t 3/4 .PACS numbers: 47.55.nd, 62.20.Mk, 47.20.Dr, 47.20.Gv The surface-tension driven spreading of liquids is industrially and biologically important, and has been studied in detail on both solid and liquid substrates [1,2,3]. Less is known about how droplet spreading is modified in the presence of a compliant substrate, a situation especially relevant to biological applications [4,5]. We perform droplet-spreading experiments on gel agar, a viscoelastic material, to explore the influence of substrate on the spreading dynamics of the droplet. We find a novel branching instability with an onset that is controlled by the ratio of surface tension difference to the shear strength of the gel. The existence of a spreading morphology in which a spreading droplet becomes spatially localized has important implications for the industrial and medical application of surfactants.Droplets spread differently on liquids, which are mobile, than on solids, which are essentially rigid [3,6,7]. The present experiments on spreading on a viscoelastic substrate (gel agar) are intended as a way to span these two limits: by increasing the agar concentration, one can tune the substrate from liquid-like to solid-like behavior. The difference in surface tension between the droplet (PDMS, a silicone oil; or Triton X-305, a surfactant solution) and the substrate drives the spreading process.Previous work on the spreading of droplets on gel substrates [8,9] showed circular spreading with rates intermediate between those observed on solid and liquid substrates, contrary to what we find. In addition, prior studies of viscoelastic substrates have focused on substrate breakup or fracture when subjected to stresses [10,11,12,13]. Here, we observe a failure of the gel driven by surface tension. After the initial failure, there are two morphologically different manifestations of the instability, influenced by both the substrate elasticity and the surface tensions, which we call starbursts and wispy drops. For weak gels (shear modulus G 30 Pa), the drop breaks into distinct crack-like spreading arms in a starburst formation, as shown in Fig. 1a. Morphologically, this is similar to cracking patterns observed in [10,12]. We observe that the arms have steep sides ex- tending into the gel and are filled with material from the spreading droplet. Above the onset of the starburst instability, the rate of spreading is found to be controlled only by the width of the arms, with collapse in the data across substrate modulus, surface tension, ...

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“…Intriguingly, recent work on the surfactantinduced fracture of a particle raft [12], saw a multi-armed morphology similar to the starbursts observed here and t 3/4 spreading behavior, which the authors associated with liquid-on-liquid behavior.…”

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confidence: 97%

Instabilities in Droplets Spreading on Gels

et al. 2007

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“…Vella et al [35] observed that adding surfactant could disrupt particle layers attached to planar water surfaces. They examined densely packed monolayers of polymeric particles ( r p = 50 μm) on the surfaces of water-glycerol solutions.…”

Section: Detaching Particles From Fluid Interfacesmentioning

confidence: 99%

“…They used a needle to inject a drop of non-ionic surfactant (polyoxyethylene sorbitan monoleate) into the layer. Providing the particles were not jammed together, Vella et al [35] observed a crack form, where the needle touched the particles, and propagate through the monolayer. They argued that localised reduction of the surface tension caused tensile stress in the particle layer, forcing the particles to rearrange [35].…”

Section: Detaching Particles From Fluid Interfacesmentioning

confidence: 99%

Controlling Pickering Emulsion Destabilisation: A Route to Fabricating New Materials by Phase Inversion

Whitby

Wanless

2016

Materials

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The aim of this paper is to review the key findings about how particle-stabilised (or Pickering) emulsions respond to stress and break down. Over the last ten years, new insights have been gained into how particles attached to droplet (and bubble) surfaces alter the destabilisation mechanisms in emulsions. The conditions under which chemical demulsifiers displace, or detach, particles from the interface were established. Mass transfer between drops and the continuous phase was shown to disrupt the layers of particles attached to drop surfaces. The criteria for causing coalescence by applying physical stress (shear or compression) to Pickering emulsions were characterised. These findings are being used to design the structures of materials formed by breaking Pickering emulsions.

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“…This process occurs mainly at the atomic scale near the crack tip, where the energy focuses, but also at much larger scale for particle rafts [21]. Nevertheless, macroscopic parameters, like work of fracture γ or fracture toughness K, can be defined (and measured) to describe the progression of cracks when the material properties are uniform without necessarily resorting to microscopic analysis [1,22,23].…”

Section: Introductionmentioning

confidence: 99%

Tearing of thin sheets: Cracks interacting through an elastic ridge

Brau

2014

Phys. Rev. E

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We study the interaction between two cracks propagating quasistatically during the tearing of a thin brittle sheet. We show that the cracks attract each other following a path described by a power law resulting from the competition between elastic and fracture energies. The power law exponent (8/11) is in close agreement with experiments. We also show that a second (asymptotic) regime, with an exponent of 9/8, emerges for small distances between the two crack tips due to the finite transverse curvature of the elastic ridge joining them.

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Dynamics of Surfactant-Driven Fracture of Particle Rafts

Cited by 37 publications

References 13 publications

Instabilities in Droplets Spreading on Gels

Instabilities in Droplets Spreading on Gels

Controlling Pickering Emulsion Destabilisation: A Route to Fabricating New Materials by Phase Inversion

Tearing of thin sheets: Cracks interacting through an elastic ridge

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