We show that thin sheets under boundary confinement spontaneously generate a
universal self-similar hierarchy of wrinkles. From simple geometry arguments
and energy scalings, we develop a formalism based on wrinklons, the transition
zone in the merging of two wrinkles, as building-blocks of the global pattern.
Contrary to the case of crumple paper where elastic energy is focused, this
transition is described as smooth in agreement with a recent numerical work.
This formalism is validated from hundreds of nm for graphene sheets to meters
for ordinary curtains, which shows the universality of our description. We
finally describe the effect of an external tension to the distribution of the
wrinkles.Comment: 7 pages, 4 figures, added references, submitted for publicatio

A. V. Pogorelov

B. Audoly

Benoit Roman

Chun Ning Lau

Cyprien Gay

Fabian Brau

Hugues Vandeparre

José Bico

Miguel Piñeirua

Pascal Damman

Pedro M. Reis

Wenzhong Bao

Physical Review Letters

English

arXiv

6 pages, 4 figures, submitted for publicationInternational audienceThe drive towards miniaturization in technology is demanding for increasingly thinner components, raising new mechanical challenges. Thin films are however unstable to boundary or substrate-induced compressive loads. Moderate compression results in regular wrinkling while further confinement can lead to crumpling. Regions of stress focusing can be a hindrance, acting as nucleation points for mechanical failure. Conversely, they can be exploited constructively for tunable thin structures. For example, singular points of deformation dramatically affect the electronic properties of graphene. Here, we show that thin sheets under boundary confinement spontaneously generate a universal self-similar hierarchy of wrinkles; from strained suspended graphene to ordinary hanging curtains. We develop a formalism based on "wrinklons", a localized transition zone in the merging of two wrinkles, as building-blocks to describe these wrinkled patterns. Our approach may find applications in domains such as graphene-based electronics, fuel cell technology, thin-film solar cells or draping in virtual reality

Vandeparre, Hugues

Pineirua, Miguel

Brau, Fabian

Roman, Benoit

Bico, Jose

Gay, Cyprien

Bao, Wenzhong

Lau, Chun Ning

Reis, Pedro

Damman, Pascal

Hal-Diderot

Wrinkling Hierarchy in Constrained Thin Sheets from Suspended Graphene to Curtains

Bico, José

Reis, Pedro M.

ORBi UMONS

Vandeparre, H.

Piñeirua, M.

Roman, B.

Bico, J.

Gay, C.

Bao, W.

Lau, C.N.

DI-fusion

Wrinkling hierarchy in constrained thin sheets from suspended graphene to curtains

HAL: Hyper Article en Ligne

Crossref

HAL Portal ESPCI (Ecole Supérieure de Physique et de Chimie Industrielles)

We show that thin sheets under boundary confinement spontaneously generate a universal self-similar hierarchy of wrinkles. From simple geometry arguments and energy scalings, we develop a formalism based on wrinklons, the localized transition zone in the merging of two wrinkles, as building blocks of the global pattern. Contrary to the case of crumpled paper where elastic energy is focused, this transition is described as smooth in agreement with a recent numerical work [R. D. Schroll, E. Katifori, and B. Davidovitch, Phys. Rev. Lett. 106, 074301 (2011)]. This formalism is validated from hundreds of nanometers for graphene sheets to meters for ordinary curtains, which shows the universality of our description. We finally describe the effect of an external tension to the distribution of the wrinkles.FLEXLA

Piñeirua, Miguel

Infoscience - École polytechnique fédérale de Lausanne

https://hal.archives-ouvertes.fr/hal-00549423

Wrinkling hierarchy in constrained thin sheets from suspended graphene
  to curtains

Wrinkling hierarchy in constrained thin sheets from suspended graphene to curtains

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