Effective strain gradient continuum model of metamaterials and size effects analysis

Effective strain gradient continuum model of metamaterials and size effects analysis

In this paper, a strain gradient continuum model for a metamaterial with a periodic lattice substructure is considered. A second gradient constitutive law is postulated at the macroscopic level. The effective classical and strain gradient stiffness tensors are obtained based on asymptotic homogeniza...

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Bibliographic Details
Published in:Continuum mechanics and thermodynamics Vol. 35; no. 3; pp. 775 - 797
Main Authors: Yang, Hua, Timofeev, Dmitry, Giorgio, Ivan, Müller, Wolfgang H.
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-05-2023
Springer
Springer Nature B.V
Subjects:
Accuracy
Cantilever beams
Classical and Continuum Physics
Continuum modeling
Engineering Thermodynamics
Finite element method
Fourier transforms
Heat and Mass Transfer
Homogenization
Mathematical analysis
Mechanics
Metamaterials
Methods
Microbalances
Microstructure
Original Article
Physics
Physics and Astronomy
Size effects
Stiffness
Structural Materials
Tensors
Theoretical and Applied Mechanics
Unit cell
Effective continuum
Finite element method
Asymptotic homogenization method
Strain gradient elasticity
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Summary:In this paper, a strain gradient continuum model for a metamaterial with a periodic lattice substructure is considered. A second gradient constitutive law is postulated at the macroscopic level. The effective classical and strain gradient stiffness tensors are obtained based on asymptotic homogenization techniques using the equivalence of energy at the macro- and microscales within a so-called representative volume element. Numerical studies by means of finite element analysis were performed to investigate the effects of changing volume ratio and characteristic length for a single unit cell of the metamaterial as well as changing properties of the underlying material. It is also shown that the size effects occurring in a cantilever beam made of a periodic metamaterial can be captured with appropriate accuracy by using the identified effective stiffness tensors.
ISSN:0935-1175
1432-0959
DOI:10.1007/s00161-020-00910-3