Buckling instability of squeezed droplets

Elfring, Gwynn J.; Lauga, Eric

doi:10.1063/1.4731795

Cited by 6 publications

(2 citation statements)

References 27 publications

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“…To date, there is no explicit formula to predict the maximum force that can be applied for this geometry. Analytical treatment of the problem is rather unwieldy, but Elfring and Lauga preformed an analysis for a similar geometry that could provide a reasonable starting point.…”

Section: Methodsmentioning

confidence: 99%

Cantilevered-Capillary Force Apparatus for Measuring Multiphase Fluid Interactions

2013

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A new instrument is presented for investigating interactions between individual colloidal particles, emulsion droplets, foam bubbles, and other particle-particle or particle-surface interactions. Measurement capabilities are demonstrated by measuring interfacial tension, coalescence time for emulsion droplets, adhesion between giant multilamellar vesicles, and adhesion between model food emulsion particles. The magnitude of the interaction force that can be measured or imposed, ranges from 1 nN to 1 mN for particles ranging in size from 10 μm to 1 mm in diameter.

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Section: Methodsmentioning

confidence: 99%

Cantilevered-Capillary Force Apparatus for Measuring Multiphase Fluid Interactions

2013

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“…Viscoelastic model fluids like the Stokes/Oldroyd-B equations (38) have been used to show that speeds should decrease monotonically with the Deborah number for infinite swimming sheets (65,66) and helical bodies (52,67,68) upon the steady propagation of small amplitude waves. For small amplitude perturbations to the fluid, frequency space provides a natural decomposition of viscous and elastic effects and explains why the same Deborah number dependence arises for both undulatory and helical motion (62,69), even in confined systems (Figure 4c,d; 51,52). Mobility enhancement in a purely viscoelastic fluid thus requires large amplitude body motions, finite length, or asymmetric beating, which have been explored numerically with fixed kinematics (53), deformable bodies (54,66,70), and mixed wave speeds (71).…”

Section: Viscoelasticitymentioning

confidence: 99%

Swimming in Complex Fluids

Spagnolie

Underhill

2023

Annu. Rev. Condens. Matter Phys.

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We review the literature on swimming in complex fluids. A classification is proposed by comparing the length and timescales of a swimmer with those of nearby obstacles, interpreted broadly, extending from rigid or soft confining boundaries to molecules that confer the bulk fluid with complex stresses. A third dimension in the classification is the concentration of swimmers, which incorporates fluids whose complexity arises purely by the collective motion of swimming organisms. For each of the eight system classes that we identify, we provide a background and describe modern research findings. Although some classes have seen a great deal of attention for decades, others remain uncharted waters still open and awaiting exploration. Expected final online publication date for the Annual Review of Condensed Matter Physics, Volume 14 is March 2023. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Liquid-bridge shape stability by energy bounding

Bostwick

Steen

2015

IMA Journal of Applied Mathematics

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Buckling instability of squeezed droplets

Cited by 6 publications

References 27 publications

Cantilevered-Capillary Force Apparatus for Measuring Multiphase Fluid Interactions

Cantilevered-Capillary Force Apparatus for Measuring Multiphase Fluid Interactions

Swimming in Complex Fluids

Liquid-bridge shape stability by energy bounding

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