Generalized Continuum Models and Higher-Order Partial Differential Equations
A special issue of Mathematics (ISSN 2227-7390). This special issue belongs to the section "Difference and Differential Equations".
Deadline for manuscript submissions: 30 April 2024 | Viewed by 4198
Special Issue Editors
Interests: applied mechanics and mathematics; classical and generalized continuum mechanics; strain gradient elasticity; strain gradient plasticity; numerical methods; FEM; IGA; computational homogenization; variational homogenization; lattice structures
Interests: asymptotic homogenization; fracture and damage mechanics; mechanics of particulate media; gradient continua; mechanical metamaterials; eaves in nonlinear media; stability analysis
Special Issue Information
Dear Colleagues,
In the framework of continuum description of condensed matter, various physical phenomena, e.g., thermal conduction and deformation, are described in terms of non-stationary partial differential equations (PDEs). In particular, most natural materials are modelled within classical continuum mechanics governed by second-order PDEs, which results in size-independent constitutive behavior.
For the structures or mechanical metamaterials with highly noticeable, architected microstructure, the significance of micro-scale mechanisms in influencing macro-scale size-dependent material behaviors is nowadays largely recognized in the context of mechanics. At the continuum level, this requires incorporation of additional (besides displacements field) degrees of freedom and higher gradients of the kinematic and/or state variables, resulting in (non-)linear higher-order PDEs.
In relation to microstructured metamaterials and generalized continuum mechanics, this Special Issue collects papers covering (but not limited to) the following topics:
- Material non-linearity, e.g., plasticity and damage phenomena;
- Higher-order phase-field models for brittle and ductile fracture;
- Large deformation aspects and elastic local instabilities;
- Wave propagation phenomena;
- Frequency and amplitude band gaps;
- Higher-order computational and variational asymptotic homogenization schemes;
- Development and formulation of dimensionally reduced models for beam-, plate-, and shell-structural elements;
- Analytical and numerical methods and material parameter analysis.
Dr. Sergei Khakalo
Dr. Emilio Barchiesi
Guest Editors
Manuscript Submission Information
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Keywords
- elasticity
- plasticity
- fracture
- wave propagation
- mechanical metamaterials
- microstructure
- homogenization
- numerical methods
