Instabilities of Thin Films on a Compliant Substrate: Direct Numerical Simulations from Surface Wrinkling to Global Buckling

Nikravesh, Siavash; Ryu, Donghyeon; Shen, Yu‐Lin

doi:10.1038/s41598-020-62600-z

Cited by 54 publications

(61 citation statements)

References 62 publications

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“…The simulation domain is defined in such a way to represent a unit cell of a periodic structure. This periodic-cell approach is built upon our earlier 1D wrinkling study 37 and is now extended to full 3D simulations. One embedded imperfection is placed in the substrate adjacent to the film-substrate interface, as shown in Fig.…”

Section: Numerical Model Descriptionmentioning

confidence: 99%

“…Surface wrinkling can be captured without the need of any tedious or multi-step numerical treatments. This approach was first developed for 1D sinusoidal wrinkling simulations 35 – 37 , and was recently extended to simple forms of 3D surface wrinkles 38 . The current paper presents our first comprehensive study on surface patterns encompassing the full range of in-plane compressive loading.…”

Section: Introductionmentioning

confidence: 99%

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Direct numerical simulations of three-dimensional surface instability patterns in thin film-compliant substrate structures

Nikravesh

Ryu

Shen

2021

Sci Rep

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A comprehensive numerical study of three-dimensional surface instability patterns is presented. The formation of wrinkles is a consequence of deformation instability when a thin film, bonded to a compliant substrate, is subject to in-plane compressive loading. We apply a recently developed computational approach to directly simulate complex surface wrinkling from pre-instability to post-instability in a straightforward manner, covering the entire biaxial loading spectrum from pure uniaxial to pure equi-biaxial compression. The simulations use embedded imperfections with perturbed material properties at the film-substrate interface. This approach not only triggers the first bifurcation mode but also activates subsequent post-buckling states, thus capable of predicting the temporal evolution of wrinkle patterns in one simulation run. The state of biaxiality is found to influence the surface pattern significantly, and each bifurcation mode can be traced back to certain abrupt changes in the overall load–displacement response. Our systematic study reveals how the loading condition dictates the formation of various instability modes including one-dimensional (1D) sinusoidal wrinkles, herringbone, labyrinth, and checkerboard.

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Section: Numerical Model Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Direct numerical simulations of three-dimensional surface instability patterns in thin film-compliant substrate structures

Nikravesh

Ryu

Shen

2021

Sci Rep

Self Cite

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“…Similar surface morphologies were investigated on a buckled free‐standing thin film bilayer. [ 39,49 ] Therefore, under very high strains, the loss of the majority of small wrinkles (except the very limited amount in the valleys) effectively reduces the intensity of the optical diffraction.…”

Section: Synthetic Bioinspired Structure and Performancementioning

confidence: 99%

Flower Inspiration: Broad‐Angle Structural Color through Tunable Hierarchical Wrinkles in Thin Film Multilayers

Chen

Airoldi

Lugo

et al. 2020

Adv Funct Materials

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The petals of some flowers form hierarchical structures when nano‐scale cuticular ridges overlay bulged epidermal cells. These hierarchical structures can broaden the observable angles of iridescence. The resulting optical effect enhances the foraging efficiency of pollinators. Although efforts have been devoted to mimicking this unique broad‐angle structural color, the intrinsic tunability offered by natural systems to control such a broadened spectrum is still absent in synthetic models. A hierarchical system is developed that provides hierarchical wrinkle‐based structures that tune the observable angles for structural color. Laser diffraction measurements demonstrate that the observable angle of reflectance is broadened in proportion to the square root of the applied compressive strain. The morphology controls the diffraction pattern: the small wrinkles control the diffraction angles and the large wrinkles broaden the observable range. The development of a multi‐mode wrinkling system to produce this broad‐angle structural color only occurs within a limited range of conditions, which are experimentally discovered and theoretically modeled. Without diffractive small wrinkles, single wrinkling modes do not display structural colors. The control of wrinkling modes mimics the tunability of petals, which gives new insight into the natural system and provides a robust foundation for tunable structural color control.

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“…The analytically predicted trends for the influence of the main controlling parameters, e.g. the stiffness ratio of the film and the substrate as well as the film thickness, have been confirmed in experimental studies [6,20,[32][33][34][35][36] as well as numerical simulations [20,25,28,29,[37][38][39][40][41][42][43][44]. To date, the numerical method of choice is the finite element method (FEM).…”

Section: Introductionmentioning

confidence: 69%

“…To date, the numerical method of choice is the finite element method (FEM). To trigger the instabilities, it is customary to introduce small perturbations to the system through the mesh, boundary conditions or material properties [39]. In order to eliminate the need for subjective perturbations that might affect the resulting wrinkling pattern, in [16,37] the FEM simulation is enhanced by an eigenvalue analysis.…”

Section: Introductionmentioning

confidence: 99%

Nonlocal wrinkling instabilities in bilayered systems using peridynamics

2021

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Wrinkling instabilities occur when a stiff thin film bonded to an elastic substrate undergoes compression. Regardless of the nature of compression, this phenomenon has been extensively studied through local models based on classical continuum mechanics. However, the experimental behavior is not yet fully understood and the influence of nonlocal effects remains largely unexplored. The objective of this paper is to fill this gap from a computational perspective by investigating nonlocal wrinkling instabilities in a bilayered system. Peridynamics (PD), a nonlocal continuum formulation, serves as a tool to model nonlocal material behavior. This manuscript presents a methodology to precisely predict the critical conditions by employing an eigenvalue analysis. Our results approach the local solution when the nonlocality parameter, the horizon size, approaches zero. An experimentally observed influence of the boundaries on the wave pattern is reproduced with PD simulations which suggests nonlocal material behavior as a physical origin. The results suggest that the level of nonlocality of a material model has quantitative influence on the main wrinkling characteristics, while most trends qualitatively coincide with predictions from the local analytical solution. However, a relation between the film thickness and the critical compression is revealed that is not existent in the local theory. Moreover, an approach to determine the peridynamic material parameters across a material interface is established by introducing an interface weighting factor. This paper, for the first time, shows that adding a nonlocal perspective to the analysis of bilayer wrinkling by using PD can significantly advance our understanding of the phenomenon.

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Instabilities of Thin Films on a Compliant Substrate: Direct Numerical Simulations from Surface Wrinkling to Global Buckling

Cited by 54 publications

References 62 publications

Direct numerical simulations of three-dimensional surface instability patterns in thin film-compliant substrate structures

Direct numerical simulations of three-dimensional surface instability patterns in thin film-compliant substrate structures

Flower Inspiration: Broad‐Angle Structural Color through Tunable Hierarchical Wrinkles in Thin Film Multilayers

Nonlocal wrinkling instabilities in bilayered systems using peridynamics

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