Relaxation dynamics of capillary folding of thin elastic sheets with pinned contact lines
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Publication:6136359
DOI10.1017/jfm.2023.1051MaRDI QIDQ6136359
Publication date: 16 January 2024
Published in: Journal of Fluid Mechanics (Search for Journal in Brave)
Cites Work
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- Isogeometric shell analysis with Kirchhoff-Love elements
- An immersed boundary method for simulating vesicle dynamics in three dimensions
- Finite element modeling of lipid bilayer membranes
- A phase field approach in the numerical study of the elastic bending energy for vesicle membranes
- Semi-implicit methods for the dynamics of elastic sheets
- Fully C1‐conforming subdivision elements for finite deformation thin‐shell analysis
- Motion and Deformation of Elastic Capsules and Vesicles in Flow
- Multiple equilibria in a simple elastocapillary system
- A Simple and Efficient Method for Modeling Constant Mean Curvature Surfaces
- The interaction between viscous fingering and wrinkling in elastic-walled Hele-Shaw cells
- Capillary-induced deformations of a thin elastic sheet
- Finite element approximation for the dynamics of fluidic two-phase biomembranes
- The Shapes of Things
- Boundary conditions for the moving contact line problem
- Two-Dimensional Capillary Origami with Inextensibility and Free Triple-Contact Points
- Elastocapillarity: When Surface Tension Deforms Elastic Solids
- Instabilities in Blistering
- Airway closure: surface-tension-driven non-axisymmetric instabilities of liquid-lined elastic rings
- A Combined Capillarity and Elasticity Problem for a Thin Plate
- Numerical methods for biomembranes: Conforming subdivision methods versus non-conforming PL methods
- Dynamics of wrinkling in ultrathin elastic sheets
- Unconditionally Energy Stable Schemes for the Inextensible Interface Problem with Bending
- Continuum models for the contact line problem
- Two-Dimensional Capillary Origami with Pinned Contact Line
- Capillary origami
- The bending of an elastic beam by a liquid drop: a variational approach
- Modelling moving contact lines on inextensible elastic sheets in two dimensions
