Finite Gradient Models with Enriched RBF-Based Interpolation
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MDPI (Mathematics)
Abstract
A finite strain gradient model for the 3D analysis of materials containing spherical voids is
presented. A two-scale approach is proposed: a least-squares methodology for RVE analysis with
quadratic displacements and a full high-order continuum with both fourth-order and sixth-order
elasticity tensors. A meshless method is adopted using radial basis function interpolation with
polynomial enrichment. Both the first and second derivatives of the resulting shape functions are
described in detail. Complete expressions for the deformation gradient F and its gradient ∇F are
derived and a consistent linearization is performed to ensure the Newton solution. A total of seven
constitutive properties is required. The classical Lamé parameters corresponding to the pristine
material are considered constant. From RVE homogenization, seven properties are obtained, two
homogenized Lamé parameters plus five gradient-related properties. Two validation 3D numerical
examples are presented. The first example exhibits the size effect (i.e., the stiffening of smaller
specimens) and the second example shows the absence of stress singularity and hence the convergence
of the discretization method.
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Citation
Areias P, Melicio R, Carapau F, Carrilho Lopes J. Finite Gradient Models with Enriched RBF-Based Interpolation. Mathematics. 2022; 10(16):2876. https://doi.org/10.3390/math10162876