Second-grade elasticity revisited
Second-grade elasticity revisited
We present a compact, linearized theory for the quasi-static deformation of elastic materials whose stored energy depends on the first two gradients of the displacement (2nd-grade elastic materials). The theory targets two main issues: (i) the mechanical interpretation of the boundary conditions and (ii) the analytical form and physical interpretation of the relevant stress fields in the sense of Cauchy. Since the pioneering works of Toupin [1,2] and Mindlin et al. [3-5], a major difficulty has been the lack of a convincing mechanical interpretation of the boundary conditions, causing 2nd-grade theories to be viewed as “perturbations” of constitutive laws for simple (1st-grade) materials. The first main contribution of this work is the provision of such an interpretation based on the concept of ortho-fiber. This approach enables us to circumvent some difficulties of a well known "reduction" of 2nd-grade materials to continua with micro-structure (in the sense of Mindlin [3]) with internal constraints. A second main contribution is the deduction of the form of the linear- and angular-momentum balance laws, and related stress fields in the sense of Cauchy, as they should appear in a consistent Newtonian formulation. The viewpoint expressed in this work is substantially different from the one of Mindlin and Ehshel [5], while affinities can be found with recent studies by Dell’Isola et al. [6-8]. The merits of the new formulation and the associated numerical approach are demonstrated by stating and solving three example boundary value problems in isotropic elasticity. A general finite element discretization of the governing equations is presented, using C1-continuous interpolation, while the numerical results show excellent convergence even for relatively coarse meshes.
Gradient theories · Linearized formulation · Boundary conditions · Higher-order stresses · Linear isotropic constitutive law
748-777
Froiio, Francesco
dae744ba-a688-4454-921e-be862b3305d2
Zervos, Antonis
9e60164e-af2c-4776-af7d-dfc9a454c46e
1 March 2019
Froiio, Francesco
dae744ba-a688-4454-921e-be862b3305d2
Zervos, Antonis
9e60164e-af2c-4776-af7d-dfc9a454c46e
Froiio, Francesco and Zervos, Antonis
(2019)
Second-grade elasticity revisited.
Mathematics and Mechanics of Solids, 24 (3), .
(doi:10.1177/1081286518754616).
Abstract
We present a compact, linearized theory for the quasi-static deformation of elastic materials whose stored energy depends on the first two gradients of the displacement (2nd-grade elastic materials). The theory targets two main issues: (i) the mechanical interpretation of the boundary conditions and (ii) the analytical form and physical interpretation of the relevant stress fields in the sense of Cauchy. Since the pioneering works of Toupin [1,2] and Mindlin et al. [3-5], a major difficulty has been the lack of a convincing mechanical interpretation of the boundary conditions, causing 2nd-grade theories to be viewed as “perturbations” of constitutive laws for simple (1st-grade) materials. The first main contribution of this work is the provision of such an interpretation based on the concept of ortho-fiber. This approach enables us to circumvent some difficulties of a well known "reduction" of 2nd-grade materials to continua with micro-structure (in the sense of Mindlin [3]) with internal constraints. A second main contribution is the deduction of the form of the linear- and angular-momentum balance laws, and related stress fields in the sense of Cauchy, as they should appear in a consistent Newtonian formulation. The viewpoint expressed in this work is substantially different from the one of Mindlin and Ehshel [5], while affinities can be found with recent studies by Dell’Isola et al. [6-8]. The merits of the new formulation and the associated numerical approach are demonstrated by stating and solving three example boundary value problems in isotropic elasticity. A general finite element discretization of the governing equations is presented, using C1-continuous interpolation, while the numerical results show excellent convergence even for relatively coarse meshes.
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Accepted/In Press date: 16 December 2017
e-pub ahead of print date: 24 April 2018
Published date: 1 March 2019
Additional Information:
Dedicated to the memory of Ioannis Vardoulakis, Professor of Mechanics at N.T.U. Athens, who initiated this research and contributed significantly to it till his untimely death. Working with him was a rare privilege
Keywords:
Gradient theories · Linearized formulation · Boundary conditions · Higher-order stresses · Linear isotropic constitutive law
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Local EPrints ID: 418435
URI: http://eprints.soton.ac.uk/id/eprint/418435
PURE UUID: 88fde90b-e19d-40ca-8e5c-f921a32736c7
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Date deposited: 08 Mar 2018 17:30
Last modified: 16 Mar 2024 06:16
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Author:
Francesco Froiio
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