Capillary origami: Spontaneous wrapping of a droplet with an elastic sheet

Charlotte Py; Paul Reverdy; Lionel Doppler; José Bico; Benoît Roman; Charles N. Baroud

doi:10.1103/PhysRevLett.98.156103

Capillary origami: Spontaneous wrapping of a droplet with an elastic sheet

Charlotte Py
, Paul Reverdy
, Lionel Doppler
, José Bico
, Benoît Roman
, Charles N. Baroud

Research output: Contribution to journal › Article › peer-review

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.

Original language	English
Article number	156103
Journal	Physical Review Letters
Volume	98
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevLett.98.156103
Publication status	Published - 13 Apr 2007

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10.1103/PhysRevLett.98.156103

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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.",

author = "Charlotte Py and Paul Reverdy and Lionel Doppler and Jos{\'e} Bico and Beno{\^i}t Roman and Baroud, \{Charles N.\}",

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AU - Bico, José

AU - Roman, Benoît

AU - Baroud, Charles N.

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AB - 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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Capillary origami: Spontaneous wrapping of a droplet with an elastic sheet

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