Semiflexible filamentous composites

E.M. Huisman; C. Heussinger; C. Storm; G.T. Barkema

doi:10.1103/PhysRevLett.105.118101

Semiflexible filamentous composites

E.M. Huisman, C. Heussinger, C. Storm, G.T. Barkema

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Abstract

Inspired by the ubiquity of composite filamentous networks in nature, we investigate models of biopolymer networks that consist of interconnected floppy and stiff filaments. Numerical simulations carried out in three dimensions allow us to explore the microscopic partitioning of stresses and strains between the stiff and floppy fractions cs and cf and reveal a nontrivial relationship between the mechanical behavior and the relative fraction of stiff polymer: when there are few stiff polymers, nonpercolated stiff ‘‘inclusions‘‘ are protected from large deformations by an encompassing floppy matrix, while at higher fractions of stiff material the stiff network is independently percolated and dominates the mechanical response.

Original language	English
Article number	118101
Pages (from-to)	118101/1-118101/4
Number of pages	4
Journal	Physical Review Letters
Volume	105
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.105.118101
Publication status	Published - 2010

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abstract = "Inspired by the ubiquity of composite filamentous networks in nature, we investigate models of biopolymer networks that consist of interconnected floppy and stiff filaments. Numerical simulations carried out in three dimensions allow us to explore the microscopic partitioning of stresses and strains between the stiff and floppy fractions cs and cf and reveal a nontrivial relationship between the mechanical behavior and the relative fraction of stiff polymer: when there are few stiff polymers, nonpercolated stiff {\textquoteleft}{\textquoteleft}inclusions{\textquoteleft}{\textquoteleft} are protected from large deformations by an encompassing floppy matrix, while at higher fractions of stiff material the stiff network is independently percolated and dominates the mechanical response.",

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AU - Heussinger, C.

AU - Storm, C.

AU - Barkema, G.T.

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AB - Inspired by the ubiquity of composite filamentous networks in nature, we investigate models of biopolymer networks that consist of interconnected floppy and stiff filaments. Numerical simulations carried out in three dimensions allow us to explore the microscopic partitioning of stresses and strains between the stiff and floppy fractions cs and cf and reveal a nontrivial relationship between the mechanical behavior and the relative fraction of stiff polymer: when there are few stiff polymers, nonpercolated stiff ‘‘inclusions‘‘ are protected from large deformations by an encompassing floppy matrix, while at higher fractions of stiff material the stiff network is independently percolated and dominates the mechanical response.

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DO - 10.1103/PhysRevLett.105.118101

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JO - Physical Review Letters

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Semiflexible filamentous composites

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