Poroelasticity#

You can use the Poroelasticity component to solve the poroelasticity equation with or without inertia. Whether inertia or body forces are included is determined by the Poroelasticity property settings. Gravitational body forces are included if the gravity_field is set in the Problem. Table 29 lists the poroelastic bulk rheology implemented for the poroelasticity equation.

Table 29 Elasticity bulk rheologies.#

Bulk Rheology

Description

IsotropicLinearPoroelasticity

Isotropic, linear poroelasticity
Table 30 Properties defining elasticity bulk rheologies.#

Subfield

L

Components

solid_density

X

fluid_density

X

fluid_viscosity

X

porosity

X

body_force

O

x, y, z

gravitational_acceleration

O

x, y, z

shear_modulus

X

drained_bulk_modulus

X

fluid_bulk_modulus

X

biot_coefficient

X

isotropic_permeability

X

tensor_permeability

O

xx, yy, zz, xy, yz, xz

reference_stress

O

xx, yy, zz, xy, yz, xz

reference_strain

O

xx, yy, zz, xy, yz, xz

X: required value in auxiliary field spatial database
O: optional value in auxiliary field spatial database
L: isotropic, linear poroelasticity

Table 31 Derived subfields that are available for output for poroelasticity bulk rheologies.#

Subfield

L

Components

cauchy_stress

X

xx, yy, zz, xy, yz, xz

cauchy_strain

X

xx, yy, zz, xy, yz, xz

bulk_density

X

water_content

X

When porosity is enabled as a state variable, it will be included in the output along with the derived subfields.

See also

See Poroelasticity Component for the Pyre properties and facilities and configuration examples.