peer reviewedAlthough "classical" multi-scale methods can capture the behaviour of cellular, including lattice, materials, when considering lattices or metamaterial local instabilities, corresponding to a change of the micro-structure morphology, classical computational homogenisation methods fail. On the one hand, first order computational homogenisation, which considers a classical continuum at the macro-scale cannot capture localisation bands inherent to cell buckling propagation. On the other hand, second-order computational homogenisation, which considers a higher order continuum at the macro-scale, introduces a size effect with respect to the Representative Volume Element (RVE) size, which is problematic when the RVE has to consider s...
The computational homogenization method enables to derive the overall behavior of heterogeneous mate...
This part of the CISM course addresses basics and advanced topics onthe computational homogenization...
The literature in the field of higher-order homogenization is mainly focused on 2-D models aimed at ...
AbstractIn this work we propose to study the behavior of cellular materials using a second-order mul...
In this paper the intrinsic role of the size of the microstructural representative volume element (R...
The aim of this work is to develop an efficient multi–scale finite element framework to capture the ...
A gradient-enhanced computational homogenization procedure, that allows for the modelling of microst...
When studying the behavior of foams by multi-scale computational homogenization procedure, the micr...
Generalized continuum mechanical theories such as second gradient elasticity can consider size and l...
Cellular materials are of special interest according to their peculiar mechanical properties. In thi...
This paper presents the detailed implementation and computational aspects of a novel second-order co...
The literature in the field of higher-order homogenization is mainly focused on 2-D models aimed at ...
In this work, multi-scale methods with strain softening are developed in the contexts of damage mode...
This work presents a general formulation of small and large strain multiscale solid constitutive mod...
The computational homogenization method enables to derive the overall behavior of heterogeneous mate...
This part of the CISM course addresses basics and advanced topics onthe computational homogenization...
The literature in the field of higher-order homogenization is mainly focused on 2-D models aimed at ...
AbstractIn this work we propose to study the behavior of cellular materials using a second-order mul...
In this paper the intrinsic role of the size of the microstructural representative volume element (R...
The aim of this work is to develop an efficient multi–scale finite element framework to capture the ...
A gradient-enhanced computational homogenization procedure, that allows for the modelling of microst...
When studying the behavior of foams by multi-scale computational homogenization procedure, the micr...
Generalized continuum mechanical theories such as second gradient elasticity can consider size and l...
Cellular materials are of special interest according to their peculiar mechanical properties. In thi...
This paper presents the detailed implementation and computational aspects of a novel second-order co...
The literature in the field of higher-order homogenization is mainly focused on 2-D models aimed at ...
In this work, multi-scale methods with strain softening are developed in the contexts of damage mode...
This work presents a general formulation of small and large strain multiscale solid constitutive mod...
The computational homogenization method enables to derive the overall behavior of heterogeneous mate...
This part of the CISM course addresses basics and advanced topics onthe computational homogenization...
The literature in the field of higher-order homogenization is mainly focused on 2-D models aimed at ...