The Complexity of Folding Self-Folding Origami

Stern, Menachem; Pinson, Matthew B.; Murugan, Arvind

doi:10.1103/physrevx.7.041070

Cited by 44 publications

(72 citation statements)

References 44 publications

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“…Moreover, since our analytic framework encompasses the case of a specific bias for each pair of particle, it could potentially be regarded as a fruitful route to promote the spontaneous self-assembly of complex structures at the cost of energy dissipation. For instance, inspired by recent works [117,118], one might consider our approach to design energetic landscapes, in terms of the pair-specific bias parameters, which selectively stabilize some target molecules.…”

Section: Discussionmentioning

confidence: 99%

How Dissipation Constrains Fluctuations in Nonequilibrium Liquids: Diffusion, Structure, and Biased Interactions

et al. 2019

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The dynamics and structure of nonequilibrium liquids, driven by non-conservative forces which can be either external or internal, generically hold the signature of the net dissipation of energy in the thermostat. Yet, disentangling precisely how dissipation changes collective effects remains challenging in many-body systems due to the complex interplay between driving and particle interactions. First, we combine explicit coarse-graining and stochastic calculus to obtain simple relations between diffusion, density correlations and dissipation in nonequilibrium liquids. Based on these results, we consider large-deviation biased ensembles where trajectories mimic the effect of an external drive. The choice of the biasing function is informed by the connection between dissipation and structure derived in the first part. Using analytical and computational techniques, we show that biasing trajectories effectively renormalizes interactions in a controlled manner, thus providing intuition on how driving forces can lead to spatial organization and collective dynamics. Altogether, our results show how tuning dissipation provides a route to alter the structure and dynamics of liquids and soft materials. arXiv:1808.07838v4 [cond-mat.stat-mech]

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Section: Discussionmentioning

confidence: 99%

How Dissipation Constrains Fluctuations in Nonequilibrium Liquids: Diffusion, Structure, and Biased Interactions

et al. 2019

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“…42 The literature on thin sheets and origami has explored how to program different folding modes in sheets with desired geometry. [43][44][45] Other recent works 46,47 have designed elastic networks with extended deformation modes in response to locally applied forces, mimicking allosteric deformation in proteins. In fact, some of these works 48 design such deformations through evolutionary or gradient descent processes.…”

Section: Mechanical Metamaterialsmentioning

confidence: 99%

Bioinspired nonequilibrium search for novel materials

Murugan

Jaeger

2019

MRS Bull.

Self Cite

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“…Finally, we demonstrate how hierarchical architectures allow to extend the number of distinct reconfiguration steps. Our work establishes general principles for designing mechanical pathways, opening new avenues for self-folding media 11,12 , pluripotent materials 9,13 , and pliable devices 14 in, e.g., stretchable electronics and soft robotics 15 .…”

mentioning

confidence: 75%

“…Multistep deformations, as well as other advanced functionalities, require designs featuring a high dimensional deformation space spanned by multiple soft modes 9,13,[24][25][26][27] . However, when actuated, competition between those soft modes leads to frustration 11,12 and spatial decay of functionality 23 . Hence, multi-modal mechanical metamaterials are sofar either actuated without explicit control over their reconfiguration pathways 13,25 , or require the use of multiple actuators, one for each degree of freedom 9,27 .…”

mentioning

confidence: 99%

Multi-step self-guided pathways for shape-changing metamaterials

Coulais

Sabbadini

Vink

et al. 2018

Nature

184

131

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Multi-step pathways-which consist of a sequence of reconfigurations of a structure-are central to the functionality of various natural and artificial systems. Such pathways execute autonomously in self-guided processes such as protein folding and self-assembly, but have previously required external control to execute in macroscale mechanical systems, provided by, for example, actuators in robotics or manual folding in origami. Here we demonstrate shape-changing, macroscale mechanical metamaterials that undergo self-guided, multi-step reconfiguration in response to global uniform compression. We avoid the need for external control by using metamaterials that are made purely of passive components. The design of the metamaterials combines nonlinear mechanical elements with a multimodal architecture that enables a sequence of topological reconfigurations caused by the formation of internal self-contacts between the elements of the metamaterial. We realize the metamaterials by using computer-controlled water-jet cutting of flexible materials, and show that the multi-step pathway and final configuration can be controlled by rational design of the nonlinear mechanical elements. We also demonstrate that the self-contacts suppress errors in the pathway. Finally, we create hierarchical architectures to extend the number of distinct reconfiguration steps. Our work establishes general principles for designing mechanical pathways, opening up new avenues for self-folding media, pluripotent materials and pliable devices in areas such as stretchable electronics and soft robotics.

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The Complexity of Folding Self-Folding Origami

Cited by 44 publications

References 44 publications

How Dissipation Constrains Fluctuations in Nonequilibrium Liquids: Diffusion, Structure, and Biased Interactions

How Dissipation Constrains Fluctuations in Nonequilibrium Liquids: Diffusion, Structure, and Biased Interactions

Bioinspired nonequilibrium search for novel materials

Multi-step self-guided pathways for shape-changing metamaterials

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