FVAnisotropicDiffusion

Computes residual for anisotropic diffusion operator for finite volume method.

An anisotropic diffusion term that is discretized using the finite-volume method:

where is the diagonal tensor diffusion coefficient and is the diffusing variable. The discretized form of the equation above over en element is the following:

where denotes the surface vector of face of the element. Furthermore, the face gradient, (\nabla \phi)_f, is determined using a central difference scheme combined with non-orthogonal correction. Lastly, components of the diffusion (diagonal) tensor can be either interpolated to the face using a geometric arithmetic average:

or a harmonic average:

where is the interpolation weight, and subscripts and represent element and neighbor values.

[Mesh]
  [cmg]
    type = CartesianMeshGenerator
    dim = 2
    dx = '10 10'
    ix = '2 2'
    dy = '20'
    iy = '4'
    subdomain_id = '1 2'
  []
[]

[Variables]
  [v]
    family = MONOMIAL
    order = CONSTANT
    fv = true
  []

  [u]
    order = FIRST
    family = LAGRANGE
  []
[]

[Kernels]
  [fem_diff1]
    type = AnisotropicDiffusion
    variable = u
    tensor_coeff = '1 0 0
                    0 10 0
                    0 0 0'
    block = 1
  []

  [fem_diff2]
    type = AnisotropicDiffusion
    variable = u
    tensor_coeff = '10 0 0
                    0 10 0
                    0 0 0'
    block = 2
  []
[]

[BCs]
  [fem_left_bottom]
    type = NeumannBC
    variable = u
    boundary = 'left bottom'
    value = 1
  []
  [fem_top_right]
    type = DirichletBC
    variable = u
    boundary = 'right top'
    value = 0
  []
[]

[FVKernels]
  [diff]
    type = FVAnisotropicDiffusion
    variable = v
    coeff = coeff
  []
[]

[FVBCs]
  [left_bottom]
    type = FVNeumannBC
    variable = v
    boundary = 'left bottom'
    value = 1
  []
  [top_right]
    type = FVDirichletBC
    variable = v
    boundary = 'right top'
    value = 0
  []
[]

[Materials]
  [diff1]
    type = ADGenericVectorFunctorMaterial
    prop_names = 'coeff'
    prop_values = '1 10 1'
    block = 1
  []

  [diff2]
    type = ADGenericVectorFunctorMaterial
    prop_names = 'coeff'
    prop_values = '10 10 1'
    block = 2
  []
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'
  petsc_options_iname = '-pc_type -pc_hypre_type'
  petsc_options_value = 'hypre boomeramg'
[]

[Outputs]
  exodus = true
[]
(moose/test/tests/fvkernels/fv_anisotropic_diffusion/fv_anisotropic_diffusion.i)

Input Parameters

  • coeffThe diagonal coefficients of a diffusion tensor. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.

    C++ Type:MooseFunctorName

    Unit:(no unit assumed)

    Controllable:No

    Description:The diagonal coefficients of a diffusion tensor. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.

  • variableThe name of the variable that this residual object operates on

    C++ Type:NonlinearVariableName

    Unit:(no unit assumed)

    Controllable:No

    Description:The name of the variable that this residual object operates on

Required Parameters

  • blockThe list of blocks (ids or names) that this object will be applied

    C++ Type:std::vector<SubdomainName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The list of blocks (ids or names) that this object will be applied

  • coeff_interp_methodharmonicSwitch that can select face interpolation method for diffusion coefficients.

    Default:harmonic

    C++ Type:MooseEnum

    Unit:(no unit assumed)

    Options:average, harmonic

    Controllable:No

    Description:Switch that can select face interpolation method for diffusion coefficients.

  • prop_getter_suffixAn optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.

    C++ Type:MaterialPropertyName

    Unit:(no unit assumed)

    Controllable:No

    Description:An optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.

  • use_interpolated_stateFalseFor the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.

    Default:False

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:No

    Description:For the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.

Optional Parameters

  • absolute_value_vector_tagsThe tags for the vectors this residual object should fill with the absolute value of the residual contribution

    C++ Type:std::vector<TagName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The tags for the vectors this residual object should fill with the absolute value of the residual contribution

  • extra_matrix_tagsThe extra tags for the matrices this Kernel should fill

    C++ Type:std::vector<TagName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The extra tags for the matrices this Kernel should fill

  • extra_vector_tagsThe extra tags for the vectors this Kernel should fill

    C++ Type:std::vector<TagName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The extra tags for the vectors this Kernel should fill

  • matrix_tagssystemThe tag for the matrices this Kernel should fill

    Default:system

    C++ Type:MultiMooseEnum

    Unit:(no unit assumed)

    Options:nontime, system

    Controllable:No

    Description:The tag for the matrices this Kernel should fill

  • vector_tagsnontimeThe tag for the vectors this Kernel should fill

    Default:nontime

    C++ Type:MultiMooseEnum

    Unit:(no unit assumed)

    Options:nontime, time

    Controllable:No

    Description:The tag for the vectors this Kernel should fill

Tagging Parameters

  • boundaries_to_avoidThe set of sidesets to not execute this FVFluxKernel on. This takes precedence over force_boundary_execution to restrict to less external boundaries. By default flux kernels are executed on all internal boundaries and Dirichlet boundary conditions.

    C++ Type:std::vector<BoundaryName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The set of sidesets to not execute this FVFluxKernel on. This takes precedence over force_boundary_execution to restrict to less external boundaries. By default flux kernels are executed on all internal boundaries and Dirichlet boundary conditions.

  • boundaries_to_forceThe set of sidesets to force execution of this FVFluxKernel on. Setting force_boundary_execution to true is equivalent to listing all external mesh boundaries in this parameter.

    C++ Type:std::vector<BoundaryName>

    Unit:(no unit assumed)

    Controllable:No

    Description:The set of sidesets to force execution of this FVFluxKernel on. Setting force_boundary_execution to true is equivalent to listing all external mesh boundaries in this parameter.

  • force_boundary_executionFalseWhether to force execution of this object on all external boundaries.

    Default:False

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:No

    Description:Whether to force execution of this object on all external boundaries.

Boundary Execution Modification Parameters

  • control_tagsAdds user-defined labels for accessing object parameters via control logic.

    C++ Type:std::vector<std::string>

    Unit:(no unit assumed)

    Controllable:No

    Description:Adds user-defined labels for accessing object parameters via control logic.

  • enableTrueSet the enabled status of the MooseObject.

    Default:True

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:Yes

    Description:Set the enabled status of the MooseObject.

  • implicitTrueDetermines whether this object is calculated using an implicit or explicit form

    Default:True

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:No

    Description:Determines whether this object is calculated using an implicit or explicit form

  • seed0The seed for the master random number generator

    Default:0

    C++ Type:unsigned int

    Unit:(no unit assumed)

    Controllable:No

    Description:The seed for the master random number generator

  • use_displaced_meshFalseWhether or not this object should use the displaced mesh for computation. Note that in the case this is true but no displacements are provided in the Mesh block the undisplaced mesh will still be used.

    Default:False

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:No

    Description:Whether or not this object should use the displaced mesh for computation. Note that in the case this is true but no displacements are provided in the Mesh block the undisplaced mesh will still be used.

Advanced Parameters

  • ghost_layers2The number of layers of elements to ghost.

    Default:2

    C++ Type:unsigned short

    Unit:(no unit assumed)

    Controllable:No

    Description:The number of layers of elements to ghost.

  • use_point_neighborsFalseWhether to use point neighbors, which introduces additional ghosting to that used for simple face neighbors.

    Default:False

    C++ Type:bool

    Unit:(no unit assumed)

    Controllable:No

    Description:Whether to use point neighbors, which introduces additional ghosting to that used for simple face neighbors.

Parallel Ghosting Parameters