In this paper the intrinsic role of the size of the microstructural representative volume element (RVE) in a second-order computational homogenization is investigated. The presented second-order computational homogenization is an extension of the classical first-order computational homogenization scheme and is based on a proper incorporation of the macroscopic gradient of the deformation tensor and the associated higher-order stress measure into the multiscale framework. The macroscopic homogenized continuum obtained through this scheme is the full second gradient continuum. It is demonstrated with several examples that the size of the microstructural RVE used in a second-order computational homogenization scheme may be related to the lengt...
A procedure for second-order computational homogenization of heterogeneous materials is derived from...
Classical effective descriptions of heterogeneous materials fail to capture the influence of the spa...
The continuous increase of computational capacity has encouraged the extensive use of multiscale tec...
In this paper the intrinsic role of the size of the microstructural representative volume element (R...
This paper presents the detailed implementation and computational aspects of a novel second-order co...
A gradient-enhanced computational homogenization procedure, that allows for the modelling of microst...
Two examples illustrating microstructural size effect and higher-order deformation are considered wi...
Two homogenisation schemes (first-order or local, and second-order or non-local) are employed in thi...
This paper addresses a first-order and a second-order framework for the multiscale modelling of hete...
peer reviewedAlthough "classical" multi-scale methods can capture the behaviour of cellular, includi...
Predicting the macroscopic behaviour of materials on the basis of the mechanics of their microstruct...
This part of the CISM course addresses basics and advanced topics onthe computational homogenization...
Formulation of the scale transition equations coupling the microscopic and macroscopic variables in ...
A procedure for second-order computational homogenization of heterogeneous materials is derived from...
Classical effective descriptions of heterogeneous materials fail to capture the influence of the spa...
The continuous increase of computational capacity has encouraged the extensive use of multiscale tec...
In this paper the intrinsic role of the size of the microstructural representative volume element (R...
This paper presents the detailed implementation and computational aspects of a novel second-order co...
A gradient-enhanced computational homogenization procedure, that allows for the modelling of microst...
Two examples illustrating microstructural size effect and higher-order deformation are considered wi...
Two homogenisation schemes (first-order or local, and second-order or non-local) are employed in thi...
This paper addresses a first-order and a second-order framework for the multiscale modelling of hete...
peer reviewedAlthough "classical" multi-scale methods can capture the behaviour of cellular, includi...
Predicting the macroscopic behaviour of materials on the basis of the mechanics of their microstruct...
This part of the CISM course addresses basics and advanced topics onthe computational homogenization...
Formulation of the scale transition equations coupling the microscopic and macroscopic variables in ...
A procedure for second-order computational homogenization of heterogeneous materials is derived from...
Classical effective descriptions of heterogeneous materials fail to capture the influence of the spa...
The continuous increase of computational capacity has encouraged the extensive use of multiscale tec...