Multiple-length-scale elastic instability mimics parametric resonance of nonlinear oscillators

Spatially confined rigid membranes reorganize their morphology in response to the imposed constraints. A crumpled elastic sheet presents a complex pattern of random folds focusing the deformation energy, whereas compressing a membrane resting on a soft foundation creates a regular pattern of sinusoi...

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Bibliographic Details
Published in:Nature physics 2011-01, Vol.7 (1), p.56-60
Main Authors: Damman, Pascal, Brau, Fabian, Vandeparre, Hugues, Sabbah, Abbas, Poulard, Christophe, Boudaoud, Arezki
Format: Article
Language:English
Subjects:
Atomic
Broken symmetry
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Deformation
Elasticity
Energy distribution
Focusing
letter
Mathematical and Computational Physics
Membranes
Molecular
Morphology
Nonlinear systems
Nonlinearity
Optical and Plasma Physics
Oscillators
Parameter estimation
Physics
Physics and Astronomy
Resonance
Theoretical
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Summary:Spatially confined rigid membranes reorganize their morphology in response to the imposed constraints. A crumpled elastic sheet presents a complex pattern of random folds focusing the deformation energy, whereas compressing a membrane resting on a soft foundation creates a regular pattern of sinusoidal wrinkles with a broad distribution of energy. Here, we study the energy distribution for highly confined membranes and show the emergence of a new morphological instability triggered by a period-doubling bifurcation. A periodic self-organized focalization of the deformation energy is observed provided that an up-down symmetry breaking, induced by the intrinsic nonlinearity of the elasticity equations, occurs. The physical model, exhibiting an analogy with parametric resonance in a nonlinear oscillator, is a new theoretical toolkit to understand the morphology of various confined systems, such as coated materials or living tissues, for example wrinkled skin, internal structure of lungs, internal elastica of an artery, brain convolutions or formation of fingerprints. Moreover, it opens the way to a new kind of microfabrication design of multiperiodic or chaotic (aperiodic) surface topographythrough self-organization.
ISSN:1745-2473
1745-2481
DOI:10.1038/nphys1806