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Local micromorphic non-affine anisotropy for materials incorporating elastically bonded fibers

Local micromorphic non-affine anisotropy for materials incorporating elastically bonded fibers
Local micromorphic non-affine anisotropy for materials incorporating elastically bonded fibers
There has been increasing experimental evidence of non-affine elastic deformation mechanisms in biological soft tissues. These observations call for novel constitutive models which are able to describe the dominant underlying micro-structural kinematic aspects, in particular relative motion characteristics of different phases. This paper proposes a flexible and modular framework based on a micromorphic continuum encompassing matrix and fiber phases. In addition to the displacement field, it features so-called director fields which can independently deform and intrinsically carry orientational information. Accordingly, the fibrous constituents can be naturally associated with the micromorphic directors and their non-affine motion within the bulk material can be efficiently captured. Furthermore, constitutive relations can be formulated based on kinematic quantities specifically linked to the material response of the matrix, the fibres and their mutual interactions. Associated stress quantities are naturally derived from a micromorphic variational principle featuring dedicated governing equations for displacement and director fields. This aspect of the framework is crucial for the truly non-affine elastic deformation description. In contrast to conventional micromorphic approaches, any non-local higher-order material behaviour is excluded, thus significantly reducing the number of material parameters to a range typically found in related classical approaches. In the context of biological soft tissue modeling, the potential and applicability of the formulation is studied for a number of academic examples featuring anisotropic fiber-reinforced composite material composition to elucidate the micromorphic material response as compared with the one obtained using a classical continuum mechanics approach.
Micromorphic Continuum, Non-affine Fibre Mechanics, Soft Tissue Mechanics, Anisotropy, Generalised Continua
0022-5096
Skatulla, Sebastian
c2010a48-a18d-4d1d-b53f-cddcdd85929b
Sansour, Carlo
f1d70db8-e7e9-47fe-99dc-6495decb4c51
Limbert, Georges
a1b88cb4-c5d9-4c6e-b6c9-7f4c4aa1c2ec
Skatulla, Sebastian
c2010a48-a18d-4d1d-b53f-cddcdd85929b
Sansour, Carlo
f1d70db8-e7e9-47fe-99dc-6495decb4c51
Limbert, Georges
a1b88cb4-c5d9-4c6e-b6c9-7f4c4aa1c2ec

Skatulla, Sebastian, Sansour, Carlo and Limbert, Georges (2021) Local micromorphic non-affine anisotropy for materials incorporating elastically bonded fibers. Journal of the Mechanics and Physics of Solids, [104576]. (doi:10.1016/j.jmps.2021.104576).

Record type: Article

Abstract

There has been increasing experimental evidence of non-affine elastic deformation mechanisms in biological soft tissues. These observations call for novel constitutive models which are able to describe the dominant underlying micro-structural kinematic aspects, in particular relative motion characteristics of different phases. This paper proposes a flexible and modular framework based on a micromorphic continuum encompassing matrix and fiber phases. In addition to the displacement field, it features so-called director fields which can independently deform and intrinsically carry orientational information. Accordingly, the fibrous constituents can be naturally associated with the micromorphic directors and their non-affine motion within the bulk material can be efficiently captured. Furthermore, constitutive relations can be formulated based on kinematic quantities specifically linked to the material response of the matrix, the fibres and their mutual interactions. Associated stress quantities are naturally derived from a micromorphic variational principle featuring dedicated governing equations for displacement and director fields. This aspect of the framework is crucial for the truly non-affine elastic deformation description. In contrast to conventional micromorphic approaches, any non-local higher-order material behaviour is excluded, thus significantly reducing the number of material parameters to a range typically found in related classical approaches. In the context of biological soft tissue modeling, the potential and applicability of the formulation is studied for a number of academic examples featuring anisotropic fiber-reinforced composite material composition to elucidate the micromorphic material response as compared with the one obtained using a classical continuum mechanics approach.

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J Mech Phys Sol (2021) Skatulla-Sansour-Limbert Micromorphic_non_affine_anisotropy - Accepted Manuscript
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Accepted/In Press date: 13 July 2021
e-pub ahead of print date: 2 August 2021
Published date: 7 August 2021
Keywords: Micromorphic Continuum, Non-affine Fibre Mechanics, Soft Tissue Mechanics, Anisotropy, Generalised Continua

Identifiers

Local EPrints ID: 454421
URI: http://eprints.soton.ac.uk/id/eprint/454421
ISSN: 0022-5096
PURE UUID: 29bb961d-2157-46d3-8e7f-d43cbcb65a50

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Date deposited: 09 Feb 2022 17:35
Last modified: 17 Mar 2024 07:04

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Contributors

Author: Sebastian Skatulla
Author: Carlo Sansour
Author: Georges Limbert

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