The classical asymptotic homogenization approach for linear elastic composites with discontinuous material properties is considered as a starting point. The sharp length scale separation between the fine periodic structure and the whole material formally leads to anisotropic elastic-type balance equations on the coarse scale, where the arising fourth rank operator is to be computed solving single periodic cell problems on the fine scale. After revisiting the derivation of the problem, which here explicitly points out how the discontinuity in the individual constituents’ elastic coefficients translates into stress jump interface conditions for the cell problems, we prove that the gradient of the cell problem solution is minor symmetric and t...
In this work, we investigate the limits of classical homogenization theories pertaining to homogeniz...
Classical homogenization methods fail to reproduce the overall response of composite structures when...
The current work deals with periodic composite media undergoing fully coupled thermomechanical loadi...
The classical asymptotic homogenization approach for linear elastic composites with discontinuous ma...
Asymptotic homogenization is employed assuming a sharp length scale separation between the periodic ...
We provide a homogenization result for the energy-functional associated with a purely brittle compos...
We derive the new effective governing equations for linear elastic composites subject to a body forc...
Strain gradient theory is an accurate model for capturing the size effect and localization phenomena...
In this thesis, we first consider the periodic homogenization of the linearized elasticity equation ...
Classical homogenization techniques are known to be effective for materials with large scale separat...
Here homogenization theory is used to establish a connection between the symmetries of a periodic el...
AbstractIn this article a fibre-reinforced composite material is modelled via an approach employing ...
Micromechanics-based homogenization has been employed extensively to predict the effective propertie...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/46162/1/205_2004_Article_BF00380256.pd
AbstractA micromechanics-based approach for the derivation of the effective properties of periodic l...
In this work, we investigate the limits of classical homogenization theories pertaining to homogeniz...
Classical homogenization methods fail to reproduce the overall response of composite structures when...
The current work deals with periodic composite media undergoing fully coupled thermomechanical loadi...
The classical asymptotic homogenization approach for linear elastic composites with discontinuous ma...
Asymptotic homogenization is employed assuming a sharp length scale separation between the periodic ...
We provide a homogenization result for the energy-functional associated with a purely brittle compos...
We derive the new effective governing equations for linear elastic composites subject to a body forc...
Strain gradient theory is an accurate model for capturing the size effect and localization phenomena...
In this thesis, we first consider the periodic homogenization of the linearized elasticity equation ...
Classical homogenization techniques are known to be effective for materials with large scale separat...
Here homogenization theory is used to establish a connection between the symmetries of a periodic el...
AbstractIn this article a fibre-reinforced composite material is modelled via an approach employing ...
Micromechanics-based homogenization has been employed extensively to predict the effective propertie...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/46162/1/205_2004_Article_BF00380256.pd
AbstractA micromechanics-based approach for the derivation of the effective properties of periodic l...
In this work, we investigate the limits of classical homogenization theories pertaining to homogeniz...
Classical homogenization methods fail to reproduce the overall response of composite structures when...
The current work deals with periodic composite media undergoing fully coupled thermomechanical loadi...