Relaxation time of confined liquids under shear

Hu, Hsuan Wei; Carson, George A.; Granick, Steve

doi:10.1103/physrevlett.66.2758

Cited by 342 publications

(308 citation statements)

References 21 publications

(13 reference statements)

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“…Experiments [1035][1036][1037][1038][1039], simulations [999,1017,1040,1041] and theory [1042,1043] indicate that the degree of slip depends on the shear rate. Slip seems to occur only from a certain critical shear rate on and it increases with the shear rate.…”

Section: Methodsmentioning

confidence: 99%

Force measurements with the atomic force microscope: Technique, interpretation and applications

Butt

Cappella

Kappl

2005

Surface Science Reports

3,218

2,949

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Section: Methodsmentioning

confidence: 99%

Force measurements with the atomic force microscope: Technique, interpretation and applications

Butt

Cappella

Kappl

2005

Surface Science Reports

3,218

2,949

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“…The experimental observation of first-order confinement-induced freezing is based on the onset of a static friction and a sudden, manyorder-of-magnitude increase in viscosity when the fluid is confined to a particular separation distance [3][4][5]7,9,10]. Other experiments observed viscoelasticity in the fluid prior to the onset of a critical shear stress [1,11,12] and a continuous transition in the viscosity [2,[13][14][15][16][17][18], leading to the conclusion that the fluid was approaching a glass transition. It has been suggested that the experimental results supporting either of these theories are fundamentally in agreement and that the conflicting models arise from differences in resolution and interpretation of the results [19].…”

mentioning

confidence: 99%

Density and Phase State of a Confined Nonpolar Fluid

Kienle

Kuhl

2016

Phys. Rev. Lett.

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Measurements of the mean refractive index of a spherelike nonpolar fluid, octamethytetracylclosiloxane (OMCTS), confined between mica sheets, demonstrate direct and conclusive experimental evidence of the absence of a first-order liquid-to-solid phase transition in the fluid when confined, which has been suggested to occur from previous experimental and simulation results. The results also show that the density remains constant throughout confinement, and that the fluid is incompressible. This, along with the observation of very large increases (many orders of magnitude) in viscosity during confinement from the literature, demonstrate that the molecular motion is limited by the confining wall and not the molecular packing. In addition, the recently developed refractive index profile correction method, which enables the structural perturbation inherent at a solid-liquid interface and that of a liquid in confinement to be determined independently, was used to show that there was no measurable excess or depleted mass of OMCTS near the mica surface in bulk films or confined films of only two molecular layers.

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“…Differences in the dynamic response from the bulk behavior are quite dramatic [l]. The effective viscosities of thin films rise orders of magnitude above the bulk values with a corresponding increase in the molecular relaxation times [3]. However, it should be recognized that dynamical experiments with extensions of the surface force apparatus are conducted a t strain rates (10 -10' s-'): orders of magnitude below the strain rates which are found in the lubrication of disk drives, of micromachines, and of camshaft lifters in automobile engines (ca.…”

Section: Introductionmentioning

confidence: 99%

Nanorheology of liquid alkanes

Gupta

Cochran

Cummings

1998

Fluid Phase Equilibria

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We report molecular dynamics simulations of liquid alkanes, squalane and tetracosane, confined between moving walls to which butane chains are tethered, effectively screening the details of the wall. As in an experiment, heat is removed by thermostatting the tethered molecules. Results obtained at high strain rates, typical of practical applications, suggest little or no difference between the bulk rheology and confined flow, and the occurrence of a high degree of slip at the wall-fluid interface at the conditions studied. -i t relatively low velocities and high densities. tetracosane shows the formation of fully-extended chains at certain n-a11 spacings.

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Relaxation time of confined liquids under shear

Cited by 342 publications

References 21 publications

Force measurements with the atomic force microscope: Technique, interpretation and applications

Force measurements with the atomic force microscope: Technique, interpretation and applications

Density and Phase State of a Confined Nonpolar Fluid

Nanorheology of liquid alkanes

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