where 
is the 4th order elasticity tensor, “:” stands for the double-dot tensor product (or double contraction). The elastic strain
εel is the difference between the total strain
ε and all inelastic strains
εinel. There may also be an extra stress contribution
σex with contributions from initial stresses and viscoelastic stresses. In case of geometric nonlinearity, the second Piola-Kirchhoff stress tensor and the Green-Lagrange strain tensor are used.
According to Table 3-1, the elasticity matrix
D for isotropic materials is written in terms of Lamé parameters
λ and
μ,
Beside the Standard (11, 22, 33, 12, 23, 13 Material data ordering, the elasticity coefficients can be entered following the
Voigt notation. In the
Voigt (11, 22, 33, 23, 13, 12) Material data ordering, the sorting of indices is:
The elasticity matrix for orthotropic materials in the Standard (11, 22, 33, 12, 23, 13) Material data ordering has the following structure:
The values of Ex,
Ey,
Ez,
νxy,
νyz,
νxz,
Gxy,
Gyz, and
Gxz are supplied in designated fields in the physics interface. COMSOL Multiphysics deduces the remaining components —
νyx,
νzx, and
νzy — using the fact that the matrices
D and
D−1 are symmetric. The
compliance matrix has the following form:
The elasticity matrix in the Voigt (11, 22, 33, 23, 13, 12) Material data ordering changes the sorting of the last three elements in the elasticity matrix:
If a pair of elastic moduli is present in the material definition, the values of Ex,
Ey,
Ez,
νxy,
νyz,
νxz,
Gxy,
Gyz, and
Gxz are computed automatically. Note that the resulting elasticity matrix will be isotropic. Depending on which pair of elastic moduli that is available, the expressions in
Table 3-1 are used to find the above values.
If a pair of elastic moduli is present in the material definition, the components of the symmetric elasticity matrix D are computed using one of
Equation 3-13 to
Equation 3-15. Depending on which pair of elastic moduli that is available, the expressions in
Table 3-1 are used to compute the necessary values. In case the orthotropic properties
Ei,
νij, and
Gij are present in the material definition, the components of the symmetric elasticity matrix
D are computed using
Equation 3-16. Note that the resulting elasticity matrix will not be fully anisotropic in neither case.
The user input D matrix always contains the physical components of the elasticity tensor
where λ and
μ are the first and second Lamé elastic parameters and
g is the metric tensor.
where the strain energy density Ws(ε, T) is given by
Equation 3-12. Hence, the stress can be found as
where T0 is a reference temperature, the volumetric heat capacity
ρCp can be assumed to be independent of the temperature (Dulong-Petit law), and the elastic entropy is
where α is the thermal expansion coefficient tensor. For an isotropic material, it simplifies into
where k is the thermal conductivity matrix, and the heat source caused by the dissipation is
where 
is the strain-rate tensor and the tensor τ represents all possible inelastic stresses (for example, a viscous stress).
In many cases, the second term can be neglected in the left-hand side of Equation 3-17 because all
Tαmn are small. The resulting approximation is often called uncoupled thermoelasticity.
where k = kn is the wave number vector, and
n is the direction vector that defines the wavefront propagation direction. The wavefront is an imaginary line connecting solid particles of the same phase. The velocity of such wavefront in the direction normal to it is given by the phase velocity
c = ω/k.
where un,j is the wave polarization vector that is the eigenvector corresponding to the eigenvalue solution
of Christoffel’s equation.
.
. Thus, for an arbitrary anisotropic medium, three waves with different phase velocities can propagate in each given direction.