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Main Authors: Poulain, Stephane, Koch, Timo, Mahadevan, L., Carlson, Andreas
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.02262
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author Poulain, Stephane
Koch, Timo
Mahadevan, L.
Carlson, Andreas
author_facet Poulain, Stephane
Koch, Timo
Mahadevan, L.
Carlson, Andreas
contents Inspired by recent experiments demonstrating that vibrating elastic sheets can function as seemingly contactless suction cups, we investigate the elastohydrodynamic hovering of a thin elastic sheet vibrating near a rigid substrate. Previous theoretical work suggests that the hovering height results from a balance between the active forcing that triggers the vibrations, the bending forces associated with the sheet's deformation, the viscous lubrication flow between the sheet and the substrate, and the sheet's weight. Here, we extend this analysis beyond the asymptotic regime of weak forcing and explore the regime of strong forcing through numerical simulations. We further quantify the influence of fluid inertia and compressibility on the equilibrium hovering height and the maximum load that can be supported. Both effects are found to introduce repulsive contributions to the net force on the sheet, which can significantly reduce its adhesive strength. Beyond providing insights into soft contactless grippers and swimming near surfaces, our analysis is relevant to the elastohydrodynamics of squeeze films and near-field acoustic levitation.
format Preprint
id arxiv_https___arxiv_org_abs_2509_02262
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Viscous adhesion in vibrated sheets: elastohydrodynamics with inertia and compressibility effects
Poulain, Stephane
Koch, Timo
Mahadevan, L.
Carlson, Andreas
Fluid Dynamics
Inspired by recent experiments demonstrating that vibrating elastic sheets can function as seemingly contactless suction cups, we investigate the elastohydrodynamic hovering of a thin elastic sheet vibrating near a rigid substrate. Previous theoretical work suggests that the hovering height results from a balance between the active forcing that triggers the vibrations, the bending forces associated with the sheet's deformation, the viscous lubrication flow between the sheet and the substrate, and the sheet's weight. Here, we extend this analysis beyond the asymptotic regime of weak forcing and explore the regime of strong forcing through numerical simulations. We further quantify the influence of fluid inertia and compressibility on the equilibrium hovering height and the maximum load that can be supported. Both effects are found to introduce repulsive contributions to the net force on the sheet, which can significantly reduce its adhesive strength. Beyond providing insights into soft contactless grippers and swimming near surfaces, our analysis is relevant to the elastohydrodynamics of squeeze films and near-field acoustic levitation.
title Viscous adhesion in vibrated sheets: elastohydrodynamics with inertia and compressibility effects
topic Fluid Dynamics
url https://arxiv.org/abs/2509.02262