Direct Measurement of the Elastohydrodynamic Lift Force at the Nanoscale

Zhang, Zaicheng; Bertin, Vincent; Arshad, Muhammad; Raphaël, Élie; Salez, Thomas; Maali, Abdelhamid

doi:10.1103/physrevlett.124.054502

Cited by 30 publications

(33 citation statements)

References 37 publications

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“…Indeed, this scaling law was recently recovered experimentally in Zhang et al. (2020). We remark that the scaling will be valid for the three-dimensional case for the entire left column of the table, and the same holds for in the middle column – the reason being that the boundary layers in these cases are always small compared to the contact size.…”

Section: Discussionsupporting

confidence: 53%

Regimes of soft lubrication

et al. 2021

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Section: Discussionsupporting

confidence: 53%

Regimes of soft lubrication

et al. 2021

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“…Previous theoretical works have studied confined flows in the soft lubrication approximation and accounted for the roles of elasticity [11][12][13][14][15][16], fluid compressibility [17], the inertia of the fluid and the elastic medium [18], and viscoelasticity of the substrate [19]. More recent works have focused on elastohydrodynamic effects for liquids confined at the micro and nano scales [20][21][22], which has important consequences for surface mechanical characterization [23,24]. For symmetrical objects, the results show that elastic deformations lead to a non-symmetric pressure field and to the emergence of a friction-reducing lift force.…”

Section: Introductionmentioning

confidence: 99%

Rotation of a submerged finite cylinder moving down a soft incline

et al. 2020

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A submerged finite cylinder moving under its own weight along a soft incline lifts off and slides at a steady velocity while also spinning. Here, we experimentally quantify the steady spinning of the cylinder and show theoretically that it is due to a combination of an elastohydrodynamic torque generated by flow in the variable gap, and the viscous friction on the edges of the finitelength cylinder. The relative influence of the latter depends on the aspect ratio of the cylinder as well as the deformability of the substrate, which we express in term of a single scaled compliance parameter. By varying this compliance parameter, we show that our experimental results are consistent with a transition from an edge-effect dominated regime for short cylinders to a gapdominated elastohydrodynamic regime when the cylinder is very long.

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“…In the presence of small slippage inhomogeneities, our scaling estimate suggests that the lift force, F z,slip , has to be considered alongside other lubrication forces. For instance, using atomic-force microscopy, the elastohydrodynamic force was reported [34] to be F z,EHD ∼ nN. Considering the same experimental setup, but with a rigid substrate exhibiting an ≈1-nm slip inhomogeneity, we obtain F z,slip ∼ nN, i.e., the same order of magnitude as for the soft substrate [35].…”

Section: Motionmentioning

confidence: 95%

Lift induced by slip inhomogeneities in lubricated contacts

et al. 2020

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Lubrication forces depend to a high degree on elasticity, texture, charge, chemistry, and temperature of the interacting surfaces. Therefore, by appropriately designing surface properties, we may tailor lubrication forces to reduce friction, adhesion, and wear between sliding surfaces and control repulsion, assembly, and collision of interacting particles. Here, we show that variations of slippage on one of the contacting surfaces induce a lift force. We demonstrate the consequences of this force on the mobility of a cylinder traveling near a wall and show the emergence of particle oscillation and migration that would not otherwise occur in the Stokes flow regime. Our study has implications for understanding how inhomogeneous biological interfaces interact with their environment; we also propose a method of patterning surfaces for controlling the motion of nearby particles.

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Direct Measurement of the Elastohydrodynamic Lift Force at the Nanoscale

Cited by 30 publications

References 37 publications

Regimes of soft lubrication

Regimes of soft lubrication

Rotation of a submerged finite cylinder moving down a soft incline

Lift induced by slip inhomogeneities in lubricated contacts

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