Thermal Expansion (for Materials)

Use the subnode to add an internal thermal strain caused by changes in temperature.

The subnode is only available with some COMSOL products (see https://www.comsol.com/products/specifications/).

This section is only present when is used as a subnode to:

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in the Layered Shell interface. See the documentation for the Thermal Expansion (for Materials) node in the Layered Shell chapter.

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in the Membrane interface. See the documentation for the Thermal Expansion (for Materials) node in the Membrane chapter.

This section is only present in the in the Layered Shell interface, where it is described in the documentation for the Thermal Expansion (for Materials) node.

Model Inputs

The Tref is the temperature at which there are no thermal strains. As a default, the value is obtained from a . You can also select to enter a value or expression for the temperature locally.

The T is by default obtained from a . You can also select an existing temperature variable from a heat transfer interface (for example, ), if any temperature variables exist, or manually enter a value or expression by selecting .


	Thermal strains are proportional to the temperature, while structural strains are computed from the gradient of the displacement field. It is a good practice to match the discretization order of thermal and structural strains. When adding a Thermal Expansion subnode in a Layered Shell or Membrane interface, and the temperature field is computed by another physics interface (often the Heat Transfer in Shells interface); use a discretization one order lower for the temperature field than what is used for the displacement field. A consistent strain discretization is automatically set up for the Solid Mechanics interface.

See also

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Using Common Model Input

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Default Model Inputs and Model Input in the COMSOL Multiphysics Reference Manual.

Thermal Expansion Properties

Select an to specify how the thermal strain is entered. The default is , in which case the thermal strain is given by

here, the secant coefficient of thermal expansion α can be temperature dependent.

When is , the thermal strain is given by

where αt is the tangential coefficient of thermal expansion.

When is , enter the thermal strain dL as function of temperature explicitly.

In all three cases, the default is to take values . When entering data as , select , , or to enter one or more components for a general coefficient of the thermal expansion tensor or the thermal strain tensor. When a nonisotropic input is used, the axis orientations are given by the coordinate system selection in the parent node.


	A heat source term will be created by this node. It can be accessed from a Thermoelastic Damping node in a heat transfer interface in order to incorporate the reversed effect that heat is produced by changes in stress. The heat source term is only present when Structural Transient Behavior is set to Include inertial terms.

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Temperature-Dependent Material Data

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Thermoelastic Damping

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Entropy and Thermoelasticity


	Thermal Stresses in a Layered Plate: Application Library path Structural_Mechanics_Module/Thermal-Structure_Interaction/layered_plate MEMS_Module/Actuators/layered_plate

Location in User Interface

Context Menus

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Physics tab with , , , , , or node selected in the model tree: