Localizing softness and stress along loops in 3D topological metamaterials

Baardink, Guido; Souslov, Anton; Paulose, Jayson; Vitelli, Vincenzo

doi:10.1073/pnas.1713826115

Cited by 35 publications

(25 citation statements)

References 49 publications

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“…These works suggest that tunable amorphous materials have the flexibility required to produce elaborate designs, as recently demonstrated by mimicking the cyclical conformational motion of protein motors [Flechsig and Togashi 2018]. These promising approaches to metamaterial design are discussed elsewhere, for example in [Baardink et al 2018;Kim et al 2018;Rocklin 2017;].…”

Section: Biology As a Challenge To Theoristsmentioning

confidence: 94%

Colloquium: Proteins: The physics of amorphous evolving matter

2019

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Proteins are a matter of dual nature. As a physical object, a protein molecule is a folded chain of amino acids with multifarious biochemistry. But it is also an instantiation along an evolutionary trajectory determined by the function performed by the protein within a hierarchy of interwoven interaction networks of the cell, the organism and the population. A physical theory of proteins therefore needs to unify both aspects, the biophysical and the evolutionary. Specifically, it should provide a model of how the DNA gene is mapped into the functional phenotype of the protein.We review several physical approaches to the protein problem, focusing on a mechanical framework which treats proteins as evolvable condensed matter: Mutations introduce localized perturbations in the gene, which are translated to localized perturbations in the protein matter. A natural tool to examine how mutations shape the phenotype are Green's functions. They map the evolutionary linkage among mutations in the gene (termed epistasis) to cooperative physical interactions among the amino acids in the protein. We discuss how the mechanistic view can be applied to examine basic questions of protein evolution and design.

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Section: Biology As a Challenge To Theoristsmentioning

confidence: 94%

Colloquium: Proteins: The physics of amorphous evolving matter

2019

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“…Topology plays an important role in these elastic systems, giving rise to topologically protected phonon-edge modes at zero frequency (or floppy modes). Maxwell lattices appear in nature in systems such as fiber networks [8] and jammed packings [9], as well as in artificial metamaterials as mass-spring systems (including other mechanical devices), both insulators and Weyl semimetals [10][11][12][13][14][15][16][17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Mechanical topological insulator in zero dimensions

Lera

Álvarez

2018

Phys. Rev. B

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We study linear vibrational modes in finite isostatic Maxwell lattices, mechanical systems where the number of degrees of freedom matches the number of constraints. Recent progress in topological mechanics exploits the nontrivial topology of BDI class Hamiltonians in one dimenson and arising topological floppy modes at the edges. A finite frame, or zero-dimensional system, also exhibits a nonzero topological index according to the classification table. We construct mechanical insulating models in zero dimensions that complete the BDI classification in the available real space dimensions. We compute and interpret its nontrivial invariant Z 2 .

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“…For instance, higherorder topological insulators rely on the existence of crystal symmetries that typically limit the robustness of the edge modes. Moreover, it has been shown that protected modes can also be localized to points or lines of dimensionality lower than (d -1) in ordinary topological insu lators that have mater ial defects [11][12][13][14] . Finally, one can speculate about such systems beyond third order -in other words, beyond the octupole moment.…”

Section: From Nature 14 March 1918mentioning

confidence: 99%

Melanin triggers antifungal defences

Casadevall

2018

Nature

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Localizing softness and stress along loops in 3D topological metamaterials

Cited by 35 publications

References 49 publications

Colloquium: Proteins: The physics of amorphous evolving matter

Colloquium: Proteins: The physics of amorphous evolving matter

Mechanical topological insulator in zero dimensions

Melanin triggers antifungal defences

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