Mechanical response of semiflexible networks to localized perturbations

D.A. Head; A.M. Levine; F.C. Mac Kintosh

doi:10.1103/PhysRevE.72.061914

Mechanical response of semiflexible networks to localized perturbations

D.A. Head, A.M. Levine, F.C. Mac Kintosh

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Abstract

Previous research on semiflexible polymers including cytoskeletal networks in cells has suggested the existence of distinct regimes of elastic response, in which the strain field is either uniform (affine) or nonuniform (nonaffine) under external stress. Associated with these regimes, it has been further suggested that a mesoscopic length scale emerges, which characterizes the scale for the crossover from nonaffine to affine deformations. Here, we extend these studies by probing the response to localized forces and force dipoles. We show that the previously identified nonaffinity length [D. A. Head, Phys. Rev. E 68, 061907 (2003)] controls the mesoscopic response to point forces and the crossover to continuum elastic behavior at large distances. © 2005 The American Physical Society.

Original language	English
Journal	Physical Review E
Volume	72
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevE.72.061914
Publication status	Published - 2005

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title = "Mechanical response of semiflexible networks to localized perturbations",

abstract = "Previous research on semiflexible polymers including cytoskeletal networks in cells has suggested the existence of distinct regimes of elastic response, in which the strain field is either uniform (affine) or nonuniform (nonaffine) under external stress. Associated with these regimes, it has been further suggested that a mesoscopic length scale emerges, which characterizes the scale for the crossover from nonaffine to affine deformations. Here, we extend these studies by probing the response to localized forces and force dipoles. We show that the previously identified nonaffinity length [D. A. Head, Phys. Rev. E 68, 061907 (2003)] controls the mesoscopic response to point forces and the crossover to continuum elastic behavior at large distances. {\textcopyright} 2005 The American Physical Society.",

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AB - Previous research on semiflexible polymers including cytoskeletal networks in cells has suggested the existence of distinct regimes of elastic response, in which the strain field is either uniform (affine) or nonuniform (nonaffine) under external stress. Associated with these regimes, it has been further suggested that a mesoscopic length scale emerges, which characterizes the scale for the crossover from nonaffine to affine deformations. Here, we extend these studies by probing the response to localized forces and force dipoles. We show that the previously identified nonaffinity length [D. A. Head, Phys. Rev. E 68, 061907 (2003)] controls the mesoscopic response to point forces and the crossover to continuum elastic behavior at large distances. © 2005 The American Physical Society.

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Mechanical response of semiflexible networks to localized perturbations

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