AbstractThis work presents a geometrically nonlinear homogenization framework for composites with magneto-mechanical behavior whereby the composite can be subject to large deformation processes. The magneto-mechanical governing equations in the material description for both the overall body and its microstructure are presented, and the connections between micro- and macro-scale field variables are identified. Considering periodic boundary conditions for the microscopic unit cell, a finite element framework for computing the macroscopic field variables and the effective tangent moduli is developed. The proposed methodology is utilized to study a variety of two- and three-dimensional numerical examples. In particular, the behavior of fiber an...
In this paper, a heterogeneous multiscale method (HMM) based technique is applied to model the behav...
International audienceHard magnetorheological elastomers (h-MREs) are essentially two phase composit...
AbstractA three-dimensional multi-scale computational homogenisation framework is developed for the ...
This work presents a geometrically nonlinear homogenization framework for composites with magneto-me...
AbstractThis work presents a geometrically nonlinear homogenization framework for composites with ma...
In the present work, the behavior of heterogeneous magnetorheological composites subjected to large ...
The aim of this work is to present a general homogenization framework with application to magnetorhe...
Magnetorheological elastomers (MREs) are composite materials consisting of magnetizable particles em...
Magnetorheological elastomers (MREs) are composite materials consisting of magnetizable particles em...
The increasing use of composite materials in the technological industry (automotive, aerospace) requ...
The primary objective of this dissertation is to develop computational models that describe the over...
A variational-based homogenization method for magnetoelastic composite materials is established in a...
This work provides a family of explicit phenomenological models both in the F−H and F−B variable spa...
In this paper, a heterogeneous multiscale method (HMM) based technique is applied to model the behav...
In this paper, a heterogeneous multiscale method (HMM) based technique is applied to model the behav...
International audienceHard magnetorheological elastomers (h-MREs) are essentially two phase composit...
AbstractA three-dimensional multi-scale computational homogenisation framework is developed for the ...
This work presents a geometrically nonlinear homogenization framework for composites with magneto-me...
AbstractThis work presents a geometrically nonlinear homogenization framework for composites with ma...
In the present work, the behavior of heterogeneous magnetorheological composites subjected to large ...
The aim of this work is to present a general homogenization framework with application to magnetorhe...
Magnetorheological elastomers (MREs) are composite materials consisting of magnetizable particles em...
Magnetorheological elastomers (MREs) are composite materials consisting of magnetizable particles em...
The increasing use of composite materials in the technological industry (automotive, aerospace) requ...
The primary objective of this dissertation is to develop computational models that describe the over...
A variational-based homogenization method for magnetoelastic composite materials is established in a...
This work provides a family of explicit phenomenological models both in the F−H and F−B variable spa...
In this paper, a heterogeneous multiscale method (HMM) based technique is applied to model the behav...
In this paper, a heterogeneous multiscale method (HMM) based technique is applied to model the behav...
International audienceHard magnetorheological elastomers (h-MREs) are essentially two phase composit...
AbstractA three-dimensional multi-scale computational homogenisation framework is developed for the ...