MatDiffusionAux

construction:Undocumented Class

The MatDiffusionAux has not been documented. The content listed below should be used as a starting point for documenting the class, which includes the typical automatic documentation associated with a MooseObject; however, what is contained is ultimately determined by what is necessary to make the documentation clear for users.

Overview

Example Input File Syntax

Input Parameters

diffuse_varThe variable that's diffusing.
C++ Type:std::vector<VariableName>
Unit:(no unit assumed)
Controllable:No
Description:The variable that's diffusing.
prop_namethe name of the material property we are going to use
C++ Type:MaterialPropertyName
Unit:(no unit assumed)
Controllable:No
Description:the name of the material property we are going to use
variableThe name of the variable that this object applies to
C++ Type:AuxVariableName
Unit:(no unit assumed)
Controllable:No
Description:The name of the variable that this object applies to

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
boundaryThe list of boundaries (ids or names) from the mesh where this object applies
C++ Type:std::vector<BoundaryName>
Unit:(no unit assumed)
Controllable:No
Description:The list of boundaries (ids or names) from the mesh where this object applies
check_boundary_restrictedTrueWhether to check for multiple element sides on the boundary in the case of a boundary restricted, element aux variable. Setting this to false will allow contribution to a single element's elemental value(s) from multiple boundary sides on the same element (example: when the restricted boundary exists on two or more sides of an element, such as at a corner of a mesh
Default:True
C++ Type:bool
Unit:(no unit assumed)
Controllable:No
Description:Whether to check for multiple element sides on the boundary in the case of a boundary restricted, element aux variable. Setting this to false will allow contribution to a single element's elemental value(s) from multiple boundary sides on the same element (example: when the restricted boundary exists on two or more sides of an element, such as at a corner of a mesh
execute_onLINEAR TIMESTEP_ENDThe list of flag(s) indicating when this object should be executed. For a description of each flag, see https://mooseframework.inl.gov/source/interfaces/SetupInterface.html.
Default:LINEAR TIMESTEP_END
C++ Type:ExecFlagEnum
Unit:(no unit assumed)
Options:NONE, INITIAL, LINEAR, NONLINEAR_CONVERGENCE, NONLINEAR, POSTCHECK, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, PRE_DISPLACE
Controllable:No
Description:The list of flag(s) indicating when this object should be executed. For a description of each flag, see https://mooseframework.inl.gov/source/interfaces/SetupInterface.html.
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

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.
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

Input Files

(problems/nts-temp-delayed.i)
(problems/gmsh-two-mat-multiple-pin.i)
(problems/gmsh-3d-coupled-nts-temp.i)
(problems/msr-couple-temp-nts-2x2-10xPow.i)
(problems/gmsh-mesh-one-material.i)
(tests/nts/gen-mesh-one-material.i)
(problems/transient-jac-test.i)
(problems/gmsh-mesh-two-materials.i)
(problems/debug-precursor-action.i)
(problems/axi-nts-temp-delayed.i)
(problems/gen-mesh-one-material.i)

(problems/nts-temp-delayed.i)

[GlobalParams]
  num_groups = 2
  # temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  # power = 20
[]

[Mesh]
  file = 'cylinder.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  # [./temp]
  #   order = FIRST
  #   family = LAGRANGE
  #   # scaling = 1e-3
  # [../]
[]

[Kernels]
  # Neutronics
  # [./time_group1]
  #   type = NtTimeDerivative
  #   grou_number = 1
  #   variable = group1
  # [../]
  # [./time_group2]
  #   type = NtTimeDerivative
  #   grou_number = 2
  #   variable = group2
  # [../]
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  # [./fission_source_group1]
  #   type = CoupledFissionKernel
  #   variable = group1
  #   group_number = 1
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # [../]
  # [./fission_source_group2]
  #   type = CoupledFissionKernel
  #   variable = group2
  #   group_number = 2
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # [../]

  # # Temperature
  # [./temp_cond]
  #   type = MatDiffusion
  #   variable = temp
  #   prop_name = 'k'
  #   save_in = 'diffus_resid tot_resid'
  # [../]
  # [./temp_source]
  #   type = FissionHeatSource
  #   tot_fissions = tot_fissions
  #   variable = temp
  #   save_in = 'src_resid tot_resid'
  # [../]
[]

[AuxVariables]
  # [./Qf]
  #   family = MONOMIAL
  #   order = CONSTANT
  # [../]
  # [./diffus_temp]
  #   family = MONOMIAL
  #   order = CONSTANT
  # [../]
  # [./diffus_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./src_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./bc_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./tot_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
[]

[AuxKernels]
  # [./Qf]
  #   type = FissionHeatSourceAux
  #   variable = Qf
  #   tot_fissions = tot_fissions
  # [../]
  # [./diffus_temp]
  #   type = MatDiffusionAux
  #   variable = diffus_temp
  #   diffuse_var = temp
  #   prop_name = 'k'
  # [../]
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = 'msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k'
    prop_values = '.312' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.312 0' # Cammi 2011 at 908 K
  []
[]

[BCs]
  # [./temp]
  #   boundary = boundary
  #   type = DirichletBC
  #   variable = temp
  #   value = 900
  #   save_in = 'bc_resid tot_resid'
  # [../]
  [group1_vacuum]
    type = VacuumBC
    variable = group1
    boundary = 'all_top all_bottom'
  []
  [group2_vacuum]
    type = VacuumBC
    variable = group2
    boundary = 'all_top all_bottom'
  []
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 2
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = false

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 2
  pfactor = 1e-2
  l_max_its = 100

  # solve_type = 'PJFNK'
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

# [ICs]
#   [./temp_ic]
#     type = ConstantIC
#     variable = temp
#     value = 900
#   [../]
# []

(problems/gmsh-two-mat-multiple-pin.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 10
[]

[Mesh]
  file = '/home/lindsayad/gdrive/gmsh-scripts/2d-msr-more-pins.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-6
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.312' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.312 0' # Cammi 2011 at 908 K
  []

[]

[BCs]
  [temp]
    boundary = 'boundary'
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 4
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = true

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # petsc_options_iname = '-pc_type -sub_pc_type'
  # petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    # full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(problems/gmsh-3d-coupled-nts-temp.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 20
[]

[Mesh]
  file = 'msr-small.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    # scaling = 1e-3
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = 'msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.312' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.312 0' # Cammi 2011 at 908 K
  []
[]

[BCs]
  [temp]
    boundary = boundary
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  type = NonlinearEigen
  free_power_iterations = 2
  source_abs_tol = 1e-12
  source_rel_tol = 1e-8
  output_after_power_iterations = false

  # type = InversePowerMethod
  # max_power_iterations = 50
  # xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 2
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  # [./src_resid_post]
  #   type = NodalL2Norm
  #   variable = src_resid
  #   execute_on = nonlinear
  # [../]
  # [./diffus_resid_post]
  #   type = NodalL2Norm
  #   variable = diffus_resid
  #   execute_on = nonlinear
  # [../]
  # [./bc_resid_post]
  #   type = NodalL2Norm
  #   variable = bc_resid
  #   execute_on = nonlinear
  # [../]
  # [./tot_resid_post]
  #   type = NodalL2Norm
  #   variable = tot_resid
  #   execute_on = nonlinear
  # [../]
  # [./group1diff]
  #   type = ElementL2Diff
  #   variable = group1
  #   execute_on = 'linear timestep_end'
  #   use_displaced_mesh = false
  # [../]
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

# [ICs]
#   [./temp_ic]
#     type = ConstantIC
#     variable = temp
#     value = 900
#   [../]
# []

(problems/msr-couple-temp-nts-2x2-10xPow.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 20
[]

[Mesh]
  file = '/home/lindsayad/gdrive/gmsh-scripts/msr-small.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    # scaling = 1e-3
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.312' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.312 0' # Cammi 2011 at 908 K
  []
[]

[BCs]
  [temp]
    boundary = boundary
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  type = NonlinearEigen
  free_power_iterations = 2
  source_abs_tol = 1e-12
  source_rel_tol = 1e-8
  output_after_power_iterations = false

  # type = InversePowerMethod
  # max_power_iterations = 50
  # xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  # solve_type = 'PJFNK'
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

# [ICs]
#   [./temp_ic]
#     type = ConstantIC
#     variable = temp
#     value = 900
#   [../]
# []

(problems/gmsh-mesh-one-material.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 10
[]

[Mesh]
  file = '/home/lindsayad/gdrive/gmsh-scripts/2d-one-mat.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-6
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 0
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
[]

[BCs]
  [temp]
    boundary = 'boundary'
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 4
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = true

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # petsc_options_iname = '-pc_type -sub_pc_type'
  # petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    # full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(tests/nts/gen-mesh-one-material.i)

[GlobalParams]
  num_groups = 2
  num_precursor_groups = 8
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 10
  use_exp_form = false
  sss2_input = false
  account_delayed = false
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  xmax = 6
  ymax = 6
  nx = 15
  ny = 15
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-6
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    diffusivity = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fission_heat = tot_fission_heat
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fission_heat = tot_fission_heat
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 0
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    interp_type = spline
  []
[]

[BCs]
  [temp]
    boundary = 'left right top bottom'
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 4
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = true

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # petsc_options_iname = '-pc_type -sub_pc_type'
  # petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    # full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fission_heat]
    type = ElmIntegTotFissHeatPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(problems/transient-jac-test.i)

flow_velocity = 147 # Cammi 147 cm/s

[GlobalParams]
  num_groups = 2
  num_precursor_groups = 8
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  # power = 200000
  temperature = temp
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 1
  block_id = '0'
  block_name = 'fuel'
[]

[MeshModifiers]
  [bounding_box]
    type = SubdomainBoundingBox
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    block_id = '1'
    block_name = 'moder'
  []
[]

[Variables]
  # [./pre1]
  # [../]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-3
  []
[]

[Kernels]
  # Neutronics
  [time_group1]
    type = NtTimeDerivative
    group_number = 1
    variable = group1
  []
  [time_group2]
    type = NtTimeDerivative
    group_number = 2
    variable = group2
  []
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_flow_fuel]
    block = 'fuel'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
    uz = ${flow_velocity}
  []
  [temp_flow_moder]
    block = 'moder'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
  []
  [temp_source]
    type = TransientFissionHeatSource
    variable = temp
  []
[]

# Delayed neutron precursors

[Precursors]
  var_name_base = pre
  v_def = ${flow_velocity}
  # block = 'fuel'
  inlet_boundary = 'bottom'
  inlet_boundary_condition = 'NeumannBC'
  inlet_bc_value = 1.1
  outlet_boundary = 'top'
  temperature = temp
  incompressible_flow = false
  transient_simulation = true
  use_exp_form = false
  jac_test = true
  # initial_condition = -20
[]

# [AuxVariables]
#   [./pre1_lin]
#     family = MONOMIAL
#     order = CONSTANT
#   [../]

#   [./Qf]
#     family = MONOMIAL
#     order = CONSTANT
#   [../]
# [./diffus_temp]
#   family = MONOMIAL
#   order = CONSTANT
# [../]
# [./diffus_resid]
#   family = LAGRANGE
#   order = FIRST
# [../]
# [./src_resid]
#   family = LAGRANGE
#   order = FIRST
# [../]
# [./bc_resid]
#   family = LAGRANGE
#   order = FIRST
# [../]
# [./tot_resid]
#   family = LAGRANGE
#   order = FIRST
# [../]
# [../]

# [AuxKernels]
#   [./pre1_lin]
#     variable = pre1_lin
#     density_log = pre1
#     type = Density
#   [../]

#   [./Qf]
#     type = FissionHeatSourceAux
#     variable = Qf
#     tot_fissions = tot_fissions
#   [../]
# [./diffus_temp]
#   type = MatDiffusionAux
#   variable = diffus_temp
#   diffuse_var = temp
#   prop_name = 'k'
# [../]
# []

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.0123 3.327e-3 1357' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = 'msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.312 1.843e-3 1760' # Cammi 2011 at 908 K
  []
[]

[BCs]
  # [./temp_inlet]
  #   boundary = 'fuel_bottom graphite_bottom'
  #   type = DirichletBC
  #   variable = temp
  #   value = 900
  # [../]
  # [./temp_outlet]
  #   boundary = 'fuel_top'
  #   type = MatINSTemperatureNoBCBC
  #   variable = temp
  #   k = 'k'
  # [../]
  # [./group1_vacuum]
  #   type = VacuumBC
  #   variable = group1
  #   boundary = 'fuel_top graphite_top fuel_bottom graphite_bottom'
  # [../]
  # [./group2_vacuum]
  #   type = VacuumBC
  #   variable = group2
  #   boundary = 'fuel_top graphite_top fuel_bottom graphite_bottom'
  # [../]
[]

[Problem]
  type = FEProblem
  coord_type = RZ
  kernel_coverage_check = false
[]

[Executioner]
  type = Transient
  end_time = 10

  nl_abs_tol = 1e-11

  # solve_type = 'PJFNK'
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor -snes_test_display'
  # This system will not converge with default preconditioning; need to use asm
  petsc_options_iname = '-snes_type'
  petsc_options_value = 'test'

  dtmin = 1e-7
  [TimeStepper]
    type = IterationAdaptiveDT
    cutback_factor = 0.4
    dt = 1e-4
    growth_factor = 1.2
    optimal_iterations = 20
    nl_max_its = 50
  []
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

# [Postprocessors]
#   [./bnorm]
#     type = ElmIntegTotFissNtsPostprocessor
#     group_fluxes = 'group1 group2'
#     execute_on = linear
#   [../]
#   [./tot_fissions]
#     type = ElmIntegTotFissPostprocessor
#     execute_on = linear
#   [../]
#   [./group1norm]
#     type = ElementIntegralVariablePostprocessor
#     variable = group1
#     execute_on = linear
#   [../]
#   [./group2norm]
#     type = ElementIntegralVariablePostprocessor
#     variable = group2
#     execute_on = linear
#   [../]
#   [./group1max]
#     type = NodalExtremeValue
value_type = max
#     variable = group1
#     execute_on = timestep_end
#   [../]
#   [./group2max]
#     type = NodalExtremeValue
value_type = max
#     variable = group2
#     execute_on = timestep_end
#   [../]
#   [./group1diff]
#     type = ElementL2Diff
#     variable = group1
#     execute_on = 'linear timestep_end'
#     use_displaced_mesh = false
#   [../]
# []

[Outputs]
  [out]
    type = Exodus
    execute_on = 'initial timestep_end'
  []
  [dof_map]
    type = DOFMap
  []

[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = RandomIC
    variable = temp
    min = 900
    max = 1400
  []
  [group1_ic]
    type = RandomIC
    variable = group1
    min = 0
    max = 600
  []
  [group2_ic]
    type = RandomIC
    variable = group2
    min = 0
    max = 600
  []
  # [./pre1_ic]
  #   type = ConstantIC
  #   variable = pre1
  #   value = -20
  # [../]
[]

(problems/gmsh-mesh-two-materials.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 10
[]

[Mesh]
  file = '/home/lindsayad/gdrive/gmsh-scripts/2d-msr.msh'
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-6
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.312' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.312 0' # Cammi 2011 at 908 K
  []

[]

[BCs]
  [temp]
    boundary = 'boundary'
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 4
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = true

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # petsc_options_iname = '-pc_type -sub_pc_type'
  # petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    # full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(problems/debug-precursor-action.i)

flow_velocity = 147 # Cammi 147 cm/s

[GlobalParams]
  num_groups = 2
  num_precursor_groups = 1
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 200000
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  block_id = 0
  block_name = 'fuel'
[]

[MeshModifiers]
  [mod]
    type = SubdomainBoundingBox
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    block_id = 1
    block_name = 'moder'
  []
[]

[Variables]
  # [./pre1]
  # [../]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-3
  []
[]

[Kernels]
  # Neutronics
  # [./time_group1]
  #   type = NtTimeDerivative
  #   grou_number = 1
  #   variable = group1
  # [../]
  # [./time_group2]
  #   type = NtTimeDerivative
  #   grou_number = 2
  #   variable = group2
  # [../]
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
    temperature = temp
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
    temperature = temp
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
    temperature = temp
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
    temperature = temp
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  # [./fission_source_group1]
  #   type = CoupledFissionKernel
  #   variable = group1
  #   group_number = 1
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # temperature = temp
  # [../]
  # [./fission_source_group2]
  #   type = CoupledFissionKernel
  #   variable = group2
  #   group_number = 2
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # temperature = temp
  # [../]

  # Temperature
  # [./temp_cond]
  #   type = MatDiffusion
  #   variable = temp
  #   prop_name = 'k'
  # [../]
  [temp_flow_fuel]
    block = 'fuel'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
    uz = ${flow_velocity}
  []
  [temp_flow_moder]
    block = 'moder'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
  []
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
  []

  #   # Delayed neutron precursors
  # [./pre1_source]
  #   type = PrecursorSource
  #   variable = pre1
  #   precursor_group_number = 1
  #   temperature = temp
  # [../]
  # [./pre1_decay]
  #   type = PrecursorDecay
  #   variable = pre1
  #   precursor_group_number = 2
  #   temperature = temp
  # [../]
[]

[Precursors]
  var_name_base = pre
  # v_def = ${flow_velocity}
  # block = 'fuel'
  inlet_boundary = 'bottom'
  inlet_boundary_condition = 'DirichletBC'
  inlet_dirichlet_value = 0
  outlet_boundary = 'top'
  T = temp
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  # [./diffus_temp]
  #   family = MONOMIAL
  #   order = CONSTANT
  # [../]
  # [./diffus_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./src_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./bc_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./tot_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  # [./diffus_temp]
  #   type = MatDiffusionAux
  #   variable = diffus_temp
  #   diffuse_var = temp
  #   prop_name = 'k'
  # [../]
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.0123 3.327e-3 1357' # Cammi 2011 at 908 K
    temperature = temp
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = 'msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.312 1.843e-3 1760' # Cammi 2011 at 908 K
    temperature = temp
  []
[]

[BCs]
  [temp_inlet]
    boundary = 'bottom'
    type = DirichletBC
    variable = temp
    value = 900
  []
  [temp_outlet]
    boundary = 'top'
    type = MatINSTemperatureNoBCBC
    variable = temp
    k = 'k'
  []
  [group1_vacuum]
    type = VacuumBC
    variable = group1
    boundary = 'top bottom'
  []
  [group2_vacuum]
    type = VacuumBC
    variable = group2
    boundary = 'top bottom'
  []
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Executioner]
  type = NonlinearEigen
  free_power_iterations = 2
  source_abs_tol = 1e-12
  source_rel_tol = 1e-8
  output_after_power_iterations = false

  # type = InversePowerMethod
  # max_power_iterations = 50
  # xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.7
  pfactor = 1e-2
  l_max_its = 100

  line_search = none
  # solve_type = 'PJFNK'
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor -snes_test_display'
  # This system will not converge with default preconditioning; need to use asm
  petsc_options_iname = '-pc_type -sub_pc_type -sub_ksp_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu preonly 2 31'
  # petsc_options_iname = '-snes_type'
  # petsc_options_value = 'test'
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(problems/axi-nts-temp-delayed.i)

flow_velocity = 147 # Cammi 147 cm/s

[GlobalParams]
  num_groups = 2
  num_precursor_groups = 8
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 200000
[]

[Mesh]
  file = 'axisymm_cylinder.msh'
[]

[Variables]
  # [./pre1]
  # [../]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-3
  []
[]

[Kernels]
  # Neutronics
  # [./time_group1]
  #   type = NtTimeDerivative
  #   grou_number = 1
  #   variable = group1
  # [../]
  # [./time_group2]
  #   type = NtTimeDerivative
  #   grou_number = 2
  #   variable = group2
  # [../]
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
    temperature = temp
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
    temperature = temp
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
    temperature = temp
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
    temperature = temp
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
    temperature = temp
  []
  # [./fission_source_group1]
  #   type = CoupledFissionKernel
  #   variable = group1
  #   group_number = 1
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # temperature = temp
  # [../]
  # [./fission_source_group2]
  #   type = CoupledFissionKernel
  #   variable = group2
  #   group_number = 2
  #   num_groups = 2
  #   group_fluxes = 'group1 group2'
  # temperature = temp
  # [../]

  # Temperature
  # [./temp_cond]
  #   type = MatDiffusion
  #   variable = temp
  #   prop_name = 'k'
  # [../]
  [temp_flow_fuel]
    block = 'fuel'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
    uz = ${flow_velocity}
  []
  [temp_flow_moder]
    block = 'moder'
    type = MatINSTemperatureRZ
    variable = temp
    rho = 'rho'
    k = 'k'
    cp = 'cp'
  []
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
  []

[]

[Precursors]
  var_name_base = pre
  v_def = ${flow_velocity}
  block = 'fuel'
  inlet_boundary = 'fuel_bottom'
  inlet_boundary_condition = 'DirichletBC'
  inlet_dirichlet_value = -20
  outlet_boundary = 'fuel_top'
  T = temp
  incompressible_flow = false
  use_exp_form = true
  initial_condition = -20
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [pre1_lin]
    family = MONOMIAL
    order = CONSTANT
  []
  # [./diffus_temp]
  #   family = MONOMIAL
  #   order = CONSTANT
  # [../]
  # [./diffus_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./src_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./bc_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
  # [./tot_resid]
  #   family = LAGRANGE
  #   order = FIRST
  # [../]
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [pre1_lin]
    variable = pre1_lin
    density_log = pre1
    type = Density
  []
  # [./diffus_temp]
  #   type = MatDiffusionAux
  #   variable = diffus_temp
  #   diffuse_var = temp
  #   prop_name = 'k'
  # [../]
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 'fuel'
    property_tables_root = 'msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.0123 3.327e-3 1357' # Cammi 2011 at 908 K
    temperature = temp
  []
  [moder]
    type = GenericMoltresMaterial
    block = 'moder'
    property_tables_root = 'msr2g_enrU_fuel_922_mod_interp_'
    num_groups = 2
    num_precursor_groups = 8
    prop_names = 'k rho cp'
    prop_values = '.312 1.843e-3 1760' # Cammi 2011 at 908 K
    temperature = temp
  []
[]

[BCs]
  [temp_inlet]
    boundary = 'fuel_bottom graphite_bottom'
    type = DirichletBC
    variable = temp
    value = 900
  []
  [temp_outlet]
    boundary = 'fuel_top'
    type = MatINSTemperatureNoBCBC
    variable = temp
    k = 'k'
  []
  [group1_vacuum]
    type = VacuumBC
    variable = group1
    boundary = 'fuel_top graphite_top fuel_bottom graphite_bottom'
  []
  [group2_vacuum]
    type = VacuumBC
    variable = group2
    boundary = 'fuel_top graphite_top fuel_bottom graphite_bottom'
  []
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Executioner]
  type = NonlinearEigen
  free_power_iterations = 2
  source_abs_tol = 1e-12
  source_rel_tol = 1e-8
  output_after_power_iterations = false

  # type = InversePowerMethod
  # max_power_iterations = 50
  # xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.7
  pfactor = 1e-2
  l_max_its = 100

  # line_search = none
  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # This system will not converge with default preconditioning; need to use asm
  petsc_options_iname = '-pc_type -sub_pc_type -sub_ksp_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu preonly 2 31'
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

(problems/gen-mesh-one-material.i)

[GlobalParams]
  num_groups = 2
  temperature = temp
  group_fluxes = 'group1 group2'
  # MSRE full power = 10 MW; core volume 90 ft3
  power = 10
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  xmax = 6
  ymax = 6
  nx = 15
  ny = 15
[]

[Variables]
  [group1]
    order = FIRST
    family = LAGRANGE
  []
  [group2]
    order = FIRST
    family = LAGRANGE
  []
  [temp]
    order = FIRST
    family = LAGRANGE
    scaling = 1e-6
  []
[]

[Kernels]
  # Neutronics
  [diff_group1]
    type = GroupDiffusion
    variable = group1
    group_number = 1
  []
  [diff_group2]
    type = GroupDiffusion
    variable = group2
    group_number = 2
  []
  [sigma_r_group1]
    type = SigmaR
    variable = group1
    group_number = 1
  []
  [sigma_r_group2]
    type = SigmaR
    variable = group2
    group_number = 2
  []
  [inscatter_group1]
    type = InScatter
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [inscatter_group2]
    type = InScatter
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group1]
    type = CoupledFissionEigenKernel
    variable = group1
    group_number = 1
    num_groups = 2
    group_fluxes = 'group1 group2'
  []
  [fission_source_group2]
    type = CoupledFissionEigenKernel
    variable = group2
    group_number = 2
    num_groups = 2
    group_fluxes = 'group1 group2'
  []

  # Temperature
  [temp_cond]
    type = MatDiffusion
    variable = temp
    prop_name = 'k'
    save_in = 'diffus_resid tot_resid'
  []
  # [./temp_cond]
  #   type = HeatConduction
  #   diffusion_coefficient_name = k
  #   diffusion_coefficient_dT_name = d_k_d_temp
  #   use_displaced_mesh = false
  #   variable = temp
  # [../]
  [temp_source]
    type = FissionHeatSource
    tot_fissions = tot_fissions
    variable = temp
    save_in = 'src_resid tot_resid'
  []
[]

[AuxVariables]
  [Qf]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_temp]
    family = MONOMIAL
    order = CONSTANT
  []
  [diffus_resid]
    family = LAGRANGE
    order = FIRST
  []
  [src_resid]
    family = LAGRANGE
    order = FIRST
  []
  [bc_resid]
    family = LAGRANGE
    order = FIRST
  []
  [tot_resid]
    family = LAGRANGE
    order = FIRST
  []
[]

[AuxKernels]
  [Qf]
    type = FissionHeatSourceAux
    variable = Qf
    tot_fissions = tot_fissions
  []
  [diffus_temp]
    type = MatDiffusionAux
    variable = diffus_temp
    diffuse_var = temp
    prop_name = 'k'
  []
[]

[Materials]
  [fuel]
    type = GenericMoltresMaterial
    block = 0
    property_tables_root = '/home/lindsayad/serpent/core/examples/serpent-input/msre/msr2g_enrU_mod_953_fuel_interp_'
    num_groups = 2
    prop_names = 'k'
    prop_values = '.0123' # Cammi 2011 at 908 K
    # prop_names = 'k d_k_d_temp'
    # prop_values = '.0123 0' # Cammi 2011 at 908 K
  []
[]

[BCs]
  [temp]
    boundary = 'left right top bottom'
    type = DirichletBC
    variable = temp
    value = 900
    save_in = 'bc_resid tot_resid'
  []
  # [./temp]
  #   boundary = boundary
  #   type = VacuumBC
  #   variable = temp
  # [../]
[]

[Executioner]
  # type = NonlinearEigen
  # free_power_iterations = 4
  # source_abs_tol = 1e-12
  # source_rel_tol = 1e-8
  # output_after_power_iterations = true

  type = InversePowerMethod
  max_power_iterations = 50
  xdiff = 'group1diff'

  bx_norm = 'bnorm'
  k0 = 1.0
  pfactor = 1e-2
  l_max_its = 100

  solve_type = 'PJFNK'
  # solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  # petsc_options_iname = '-pc_type -sub_pc_type'
  # petsc_options_value = 'asm lu'
[]

[Preconditioning]
  [SMP]
    type = SMP
    # full = true
  []
[]

[Postprocessors]
  [bnorm]
    type = ElmIntegTotFissNtsPostprocessor
    group_fluxes = 'group1 group2'
    execute_on = linear
  []
  [tot_fissions]
    type = ElmIntegTotFissPostprocessor
    execute_on = linear
  []
  [group1norm]
    type = ElementIntegralVariablePostprocessor
    variable = group1
    execute_on = linear
  []
  [group2norm]
    type = ElementIntegralVariablePostprocessor
    variable = group2
    execute_on = linear
  []
  [group1max]
    type = NodalExtremeValue
    value_type = max
    variable = group1
    execute_on = timestep_end
  []
  [group2max]
    type = NodalExtremeValue
    value_type = max
    variable = group2
    execute_on = timestep_end
  []
  [src_resid_post]
    type = NodalL2Norm
    variable = src_resid
    execute_on = nonlinear
  []
  [diffus_resid_post]
    type = NodalL2Norm
    variable = diffus_resid
    execute_on = nonlinear
  []
  [bc_resid_post]
    type = NodalL2Norm
    variable = bc_resid
    execute_on = nonlinear
  []
  [tot_resid_post]
    type = NodalL2Norm
    variable = tot_resid
    execute_on = nonlinear
  []
  [group1diff]
    type = ElementL2Diff
    variable = group1
    execute_on = 'linear timestep_end'
    use_displaced_mesh = false
  []
[]

[Outputs]
  [out]
    type = Exodus
    execute_on = 'timestep_end'
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[ICs]
  [temp_ic]
    type = ConstantIC
    variable = temp
    value = 900
  []
[]

Overview
Example Input File Syntax
Input Parameters
Input Files