We define stress and strain splittings appropriate to linearly elastic anisotropic materials with volumetric constraints. The treatment includes rigidtropic materials, which develop no strains under a stress pattern that is a null eigenvector of the compliance matrix. This model includes as special case incompressible materials, for which the eigenvector is hydrostatic stress. The main finding is that pressure and volumetric strain must be redefined as effective quantities. Using this idea, an energy decomposition that exactly separates deviatoric and volumetric energy follows
The parametric equations of the strength surface in the space of internal force factors (IFF) are gi...
Materials for which the stiffness under hydrostatic loads (bulk modulus) is very high compared to th...
We describe a non-linear anisotropic hyperelastic model appropriate for geomaterials, deriving the f...
We define stress and strain splittings appropriate to linearly elastic anisotropic materia...
We study three “incompressibility flavors” of linearly-elastic anisotropic solids that e...
We give conditions on the strain-energy function of nonlinear anisotropic hyperelastic materials tha...
We give conditions on the strain–energy function of nonlinear anisotropic hyperelastic materials tha...
Abstract We give conditions on the strain–energy function of nonlinear anisotropic hyperelastic mate...
Incompressible nonlinearly hyperelastic materials are rarely simulated in finite element numerical e...
In the field of configurational mechanics we study energetic changes associated to variations of mat...
Anisotropic elastic materials, such as homogenized model of fiber-reinforced matrix, can display nea...
In order to avoid the numerical difficulties in locally enforcing the incompressibility constraint u...
In order to avoid the numerical difficulties in locally enforcing the incompressibility constraint u...
In order to study the elastic behaviour of matter when subjected to very large pressures, such as oc...
In order to study the elastic behaviour of matter when subjected to very large pressures, such as oc...
The parametric equations of the strength surface in the space of internal force factors (IFF) are gi...
Materials for which the stiffness under hydrostatic loads (bulk modulus) is very high compared to th...
We describe a non-linear anisotropic hyperelastic model appropriate for geomaterials, deriving the f...
We define stress and strain splittings appropriate to linearly elastic anisotropic materia...
We study three “incompressibility flavors” of linearly-elastic anisotropic solids that e...
We give conditions on the strain-energy function of nonlinear anisotropic hyperelastic materials tha...
We give conditions on the strain–energy function of nonlinear anisotropic hyperelastic materials tha...
Abstract We give conditions on the strain–energy function of nonlinear anisotropic hyperelastic mate...
Incompressible nonlinearly hyperelastic materials are rarely simulated in finite element numerical e...
In the field of configurational mechanics we study energetic changes associated to variations of mat...
Anisotropic elastic materials, such as homogenized model of fiber-reinforced matrix, can display nea...
In order to avoid the numerical difficulties in locally enforcing the incompressibility constraint u...
In order to avoid the numerical difficulties in locally enforcing the incompressibility constraint u...
In order to study the elastic behaviour of matter when subjected to very large pressures, such as oc...
In order to study the elastic behaviour of matter when subjected to very large pressures, such as oc...
The parametric equations of the strength surface in the space of internal force factors (IFF) are gi...
Materials for which the stiffness under hydrostatic loads (bulk modulus) is very high compared to th...
We describe a non-linear anisotropic hyperelastic model appropriate for geomaterials, deriving the f...