Hygromorphs: From pine cones to biomimetic bilayers

E. Reyssat; L. Mahadevan

doi:10.1098/rsif.2009.0184

Hygromorphs: From pine cones to biomimetic bilayers

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

Abstract

We consider natural and artificial hygromorphs, objects that respond to environmental humidity by changing their shape. Using the pine cone as an example that opens when dried and closes when wet, we quantify the geometry, mechanics and dynamics of closure and opening at the cell, tissue and organ levels, building on our prior structural knowledge. A simple scaling theory allows us to quantify the hysteretic dynamics of opening and closing. We also show how simple bilayer hygromorphs of paper and polymer show similar behaviour that can be quantified via a theory which couples fluid transport in a porous medium and evaporative flux to mechanics and geometry. Our work unifies varied observations of natural hygromorphs and suggests interesting biomimetic analogues, which we illustrate using an artificial flower with a controllable blooming and closing response.

Original language	English
Pages (from-to)	951-957
Number of pages	7
Journal	Journal of the Royal Society Interface
Volume	6
Issue number	39
DOIs	https://doi.org/10.1098/rsif.2009.0184
Publication status	Published - 6 Oct 2009
Externally published	Yes

Keywords

Biomimetics
Pine cone
Swelling
Wicking

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10.1098/rsif.2009.0184

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abstract = "We consider natural and artificial hygromorphs, objects that respond to environmental humidity by changing their shape. Using the pine cone as an example that opens when dried and closes when wet, we quantify the geometry, mechanics and dynamics of closure and opening at the cell, tissue and organ levels, building on our prior structural knowledge. A simple scaling theory allows us to quantify the hysteretic dynamics of opening and closing. We also show how simple bilayer hygromorphs of paper and polymer show similar behaviour that can be quantified via a theory which couples fluid transport in a porous medium and evaporative flux to mechanics and geometry. Our work unifies varied observations of natural hygromorphs and suggests interesting biomimetic analogues, which we illustrate using an artificial flower with a controllable blooming and closing response.",

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author = "E. Reyssat and L. Mahadevan",

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AU - Mahadevan, L.

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N2 - We consider natural and artificial hygromorphs, objects that respond to environmental humidity by changing their shape. Using the pine cone as an example that opens when dried and closes when wet, we quantify the geometry, mechanics and dynamics of closure and opening at the cell, tissue and organ levels, building on our prior structural knowledge. A simple scaling theory allows us to quantify the hysteretic dynamics of opening and closing. We also show how simple bilayer hygromorphs of paper and polymer show similar behaviour that can be quantified via a theory which couples fluid transport in a porous medium and evaporative flux to mechanics and geometry. Our work unifies varied observations of natural hygromorphs and suggests interesting biomimetic analogues, which we illustrate using an artificial flower with a controllable blooming and closing response.

AB - We consider natural and artificial hygromorphs, objects that respond to environmental humidity by changing their shape. Using the pine cone as an example that opens when dried and closes when wet, we quantify the geometry, mechanics and dynamics of closure and opening at the cell, tissue and organ levels, building on our prior structural knowledge. A simple scaling theory allows us to quantify the hysteretic dynamics of opening and closing. We also show how simple bilayer hygromorphs of paper and polymer show similar behaviour that can be quantified via a theory which couples fluid transport in a porous medium and evaporative flux to mechanics and geometry. Our work unifies varied observations of natural hygromorphs and suggests interesting biomimetic analogues, which we illustrate using an artificial flower with a controllable blooming and closing response.

KW - Biomimetics

KW - Pine cone

KW - Swelling

KW - Wicking

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DO - 10.1098/rsif.2009.0184

M3 - Article

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AN - SCOPUS:69949108775

SN - 1742-5689

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EP - 957

JO - Journal of the Royal Society Interface

JF - Journal of the Royal Society Interface

IS - 39

ER -

Hygromorphs: From pine cones to biomimetic bilayers

Abstract

Keywords

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