Capillary Origami: Spontaneous Wrapping of a Droplet with an Elastic Sheet

Py, Charlotte; Reverdy, Paul; Doppler, Lionel; Bico, José; Roman, Benoit; Baroud, Charles N

doi:10.1103/PhysRevLett.98.156103

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Capillary Origami: Spontaneous Wrapping of a Droplet with an Elastic Sheet

Author(s): Charlotte Py , Paul Reverdy , Lionel Doppler , José Bico , Benoît Roman , Charles N. Baroud

Publication date (Electronic): April 13 2007

Journal: Physical Review Letters

Publisher: American Physical Society (APS)

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Abstract

The interaction between elasticity and capillarity is used to produce three-dimensional structures through the wrapping of a liquid droplet by a planar sheet. The final encapsulated 3D shape is controlled by tailoring the initial geometry of the flat membrane. Balancing interfacial energy with elastic bending energy provides a critical length scale below which encapsulation cannot occur, which is verified experimentally. This length is found to depend on the thickness as h3/2, a scaling favorable to miniaturization which suggests a new way of mass production of 3D micro- or nanoscale objects.

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Most cited references 19

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Theory of Elasticity: Vol. 7 of Course of Theoretical Physics

L. D. Landau, E Lifshitz, J. B. Sykes … (1960)

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Adhesion: elastocapillary coalescence in wet hair.

Arezki Boudaoud, José Bico, Loïc Moulin … (2004)

We investigated why wet hair clumps into bundles by dunking a model brush of parallel elastic lamellae into a perfectly wetting liquid. As the brush is withdrawn, pairs of bundles aggregate successively, forming complex hierarchical patterns that depend on a balance between capillary forces and the elasticity of the lamellae. This capillary-driven self-assembly of flexible structures, which occurs in the tarsi of insects and in biomimetic adhesives but which can also damage micro-electromechanical structures or carbon nanotube 'carpets', represents a new type of coalescence process.