The Nonlinear Elastic Material feature is used to model stress-strain relationships which are nonlinear even at infinitesimal strains. It is available in the Solid Mechanics and Membrane interfaces. This material model requires either the Nonlinear Structural Materials Module or the Geomechanics Module.

By adding the following subnodes to the Nonlinear Elastic Material node you can incorporate many other effects:

Note: Some options are only available with certain COMSOL products (see http://www.comsol.com/products/specifications/)

The Global coordinate system is selected by default. The Coordinate system list contains any additional coordinate systems that the model includes (except boundary coordinate systems). The coordinate system is used when stresses or strains are presented in a local system. The coordinate system must have orthonormal coordinate axes, and be defined in the material frame. Many of the possible subnodes inherit the coordinate system settings.

Nonlinear Structural Materials Module: Select a Material model: Ramberg-Osgood, Power law, Uniaxial data, Bilinear elastic, or User defined.

Geomechanics Module: Select a Material model: Ramberg-Osgood, Hyperbolic law, Hardin-Drnevich, Duncan-Chang, Duncan-Selig, or User defined.

All nonlinear elastic material models have density as an input. The default Density ρ uses values From material. For User defined enter another value or expression.

If any material in the model has a temperature dependent mass density, and From material is selected, the Volume reference temperature list will appear in the Model Input section. As a default, the value of Tref is obtained from a Common model input. You can also select User defined to enter a value or expression for the reference temperature locally.

For a material with a very low compressibility, using only displacements as degrees of freedom may lead to a numerically ill-posed problem. You can then use a mixed formulation, which add an extra dependent variable for either the pressure or for the volumetric strain, see the Mixed Formulation section in the Structural Mechanics Theory chapter.

From the Use mixed formulation list, select None, Pressure formulation, or Strain formulation.

Select from the applicable list to use the value From material or enter a User defined value or expression.

From the Specify list select a pair of elastic properties for an isotropic material — Young’s modulus and Poisson’s ratio (the default for Ramberg-Osgood, Power law, Duncan-Chang, and Duncan-Selig) or Bulk modulus and shear modulus (the default for Hyperbolic law and Hardin-Drnevich).

For Uniaxial data enter a value or expression for the Uniaxial stress function σax as a function of the uniaxial strain. The default expression is the linear function (210[GPa])*solid.eax N/m2, which corresponds to a linear elastic material with Young’s modulus 210 GPa.

From the Specify list select how to specify the second elastic property for the material — Bulk modulus or Poisson’s ratio. Then, depending on the selection, enter a value or select from the applicable list to use the value From material or enter a User defined value or expression:

When you select Bulk modulus, the Young’s modulus is computed from the tensile part of the Uniaxial stress function σax. When you select Poisson’s ratio, you can either use the tensile part (default), or use the full tensile-compressive function by selecting the check box Use nonsymmetric stress-strain data.

For Bilinear elastic enter a value or select from the applicable list to use the value From material or enter a User defined value or expression.

In the User defined material model, you specify the bulk modulus implicitly by entering the relation between pressure and volumetric elastic strain. Enter a value or select from the applicable list to use the value From material or enter a User defined value or expression.

If a study step is geometrically nonlinear, the default behavior is to use a large strain formulation in all domains. Select the Force linear strains check box to always use a small strain formulation, irrespective of the setting in the study step.

When a geometrically nonlinear formulation is used, the elastic deformations used for computing the stresses can be obtained in two different ways if inelastic deformations are present: additive decomposition and multiplicative decomposition. The default is to use multiplicative decomposition. Select Additive strain decomposition to change to an assumption of additivity.

To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box.

Select the Calculate dissipated energy check box as needed to compute the energy dissipated by Creep, Plasticity, Viscoplasticity, or Viscoelasticity.

Physics tab with Solid Mechanics selected:

Physics tab with Membrane selected: