KStandardDeviation

Extract the k standard deviation computed by OpenMC

Description

This postprocessor extracts the $var element = document.getElementById("moose-equation-7f280115-dc14-4b0a-ba38-a39742208c93");katex.render("k", element, {displayMode:false,throwOnError:false});$ standard deviation from the latest OpenMC eigenvalue calculation. OpenMC contains four different methods for evaluating the $var element = document.getElementById("moose-equation-b0027ffa-d73e-4ed8-bf93-98bc9639d56a");katex.render("k", element, {displayMode:false,throwOnError:false});$ eigenvalue (which each has an associated standard deviation), each of which can be selected here by setting the value_type parameter:

collision: collision estimator
absorption: absorption estimator
tracklength: tracklength estimator
combined: (default) minimum variance estimate based on combining the collision, absorption, and tracklength estimates.

Example Input Syntax

Shown below is an example for each of the four available estimators.

[Postprocessors]
  [k_collision]
    type = KEigenvalue
    value_type = 'collision'
  []
  [k_absorption]
    type = KEigenvalue
    value_type = 'absorption'
  []
  [k_tracklength]
    type = KEigenvalue
    value_type = 'tracklength'
  []
  [k_combined]
    type = KEigenvalue
    value_type = 'combined'
  []
  [k_collision_std_dev]
    type = KStandardDeviation
    value_type = 'collision'
  []
  [k_absorption_std_dev]
    type = KStandardDeviation
    value_type = 'absorption'
  []
  [k_tracklength_std_dev]
    type = KStandardDeviation
    value_type = 'tracklength'
  []
  [k_combined_std_dev]
    type = KStandardDeviation
    value_type = 'combined'
  []
[]

Input Parameters

execute_onTIMESTEP_ENDThe list of flag(s) indicating when this object should be executed, the available options include NONE, INITIAL, LINEAR, NONLINEAR, POSTCHECK, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM.
Default:TIMESTEP_END
C++ Type:ExecFlagEnum
Options:NONE, INITIAL, LINEAR, NONLINEAR, POSTCHECK, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, TRANSFER
Controllable:No
Description:The list of flag(s) indicating when this object should be executed, the available options include NONE, INITIAL, LINEAR, NONLINEAR, POSTCHECK, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM.
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
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
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.
value_typecombinedType of eigenvalue global tally to report
Default:combined
C++ Type:MooseEnum
Options:collision, absorption, tracklength, combined
Controllable:No
Description:Type of eigenvalue global tally to report

Optional Parameters

allow_duplicate_execution_on_initialFalseIn the case where this UserObject is depended upon by an initial condition, allow it to be executed twice during the initial setup (once before the IC and again after mesh adaptivity (if applicable).
Default:False
C++ Type:bool
Controllable:No
Description:In the case where this UserObject is depended upon by an initial condition, allow it to be executed twice during the initial setup (once before the IC and again after mesh adaptivity (if applicable).
control_tagsAdds user-defined labels for accessing object parameters via control logic.
C++ Type:std::vector<std::string>
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
Controllable:Yes
Description:Set the enabled status of the MooseObject.
execution_order_group0Execution order groups are executed in increasing order (e.g., the lowest number is executed first). Note that negative group numbers may be used to execute groups before the default (0) group. Please refer to the user object documentation for ordering of user object execution within a group.
Default:0
C++ Type:int
Controllable:No
Description:Execution order groups are executed in increasing order (e.g., the lowest number is executed first). Note that negative group numbers may be used to execute groups before the default (0) group. Please refer to the user object documentation for ordering of user object execution within a group.
force_postauxFalseForces the UserObject to be executed in POSTAUX
Default:False
C++ Type:bool
Controllable:No
Description:Forces the UserObject to be executed in POSTAUX
force_preauxFalseForces the UserObject to be executed in PREAUX
Default:False
C++ Type:bool
Controllable:No
Description:Forces the UserObject to be executed in PREAUX
force_preicFalseForces the UserObject to be executed in PREIC during initial setup
Default:False
C++ Type:bool
Controllable:No
Description:Forces the UserObject to be executed in PREIC during initial setup
outputsVector of output names where you would like to restrict the output of variables(s) associated with this object
C++ Type:std::vector<OutputName>
Controllable:No
Description:Vector of output names where you would like to restrict the output of variables(s) associated with this object
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
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

(tutorials/msfr/openmc.i)
(tutorials/gas_compact_multiphysics/openmc_thm.i)
(tutorials/gas_assembly/openmc.i)
(tutorials/pincell_multiphysics/openmc.i)
(tutorials/gas_compact_multiphysics/openmc_nek.i)
(test/tests/postprocessors/eigenvalue/openmc.i)
(test/tests/neutronics/triggers/k_std_dev.i)

(test/tests/postprocessors/eigenvalue/openmc.i)

[Mesh]
  [sphere]
    type = FileMeshGenerator
    file = ../../neutronics/meshes/sphere.e
  []
  [solid]
    type = CombinerGenerator
    inputs = sphere
    positions = '0 0 0
                 0 0 4
                 0 0 8'
  []
  [solid_ids]
    type = SubdomainIDGenerator
    input = solid
    subdomain_id = '100'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem
  power = 100.0
  temperature_blocks = '100'
  cell_level = 0
  check_tally_sum = false

  initial_properties = xml

  [Tallies]
    [Cell]
      type = CellTally
      blocks = '100'
    []
  []
[]

[Executioner]
  type = Transient
  num_steps = 1
[]

[Postprocessors]
  [k_collision]
    type = KEigenvalue
    value_type = 'collision'
  []
  [k_absorption]
    type = KEigenvalue
    value_type = 'absorption'
  []
  [k_tracklength]
    type = KEigenvalue
    value_type = 'tracklength'
  []
  [k_combined]
    type = KEigenvalue
    value_type = 'combined'
  []
  [k_collision_std_dev]
    type = KStandardDeviation
    value_type = 'collision'
  []
  [k_absorption_std_dev]
    type = KStandardDeviation
    value_type = 'absorption'
  []
  [k_tracklength_std_dev]
    type = KStandardDeviation
    value_type = 'tracklength'
  []
  [k_combined_std_dev]
    type = KStandardDeviation
    value_type = 'combined'
  []
[]

[Outputs]
  csv = true
[]

(tutorials/msfr/openmc.i)

[Mesh]
  [mesh]
    type = FileMeshGenerator
    file = msr.e
  []
[]

[ICs]
  [temp]
    type = ConstantIC
    variable = temp
    value = 948.0
  []
  [density]
    type = ConstantIC
    variable = density
    value = ${fparse -0.882*948+4983.6}
  []
[]

[AuxVariables]
  [cell_temperature]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_density]
    family = MONOMIAL
    order = CONSTANT
  []
[]

[AuxKernels]
  [cell_temperature]
    type = CellTemperatureAux
    variable = cell_temperature
  []
  [cell_density]
    type = CellDensityAux
    variable = cell_density
  []
  [density]
    type = ParsedAux
    variable = density
    expression = '-0.882*temp+4983.6'
    coupled_variables = temp
    execute_on = timestep_begin
  []
[]

[Problem]
  type = OpenMCCellAverageProblem
  verbose = true

  # this will start each Picard iteration from the fission source from the previous one
  reuse_source = true

  scaling = 100.0

  density_blocks = '1'
  temperature_blocks = '1'
  cell_level = 0

  power = 300.0e6

  relaxation = dufek_gudowski
  first_iteration_particles = 5000

  skinner = moab

  [Tallies]
    [heat_source]
      type = MeshTally
      mesh_template = msr.e
      output = unrelaxed_tally_std_dev
    []
  []
[]

nb = 15.0
tmin = 800.0
tmax = 1150.0

[UserObjects]
  [moab]
    type = MoabSkinner
    temperature = temp
    n_temperature_bins = ${nb}
    temperature_min = ${tmin}
    temperature_max = ${tmax}

    density = density
    n_density_bins = ${nb}
    density_min = ${fparse -0.882*tmax+4983.6}
    density_max = ${fparse -0.882*tmin+4983.6}

    build_graveyard = true
    output_skins = true
  []
[]

[MultiApps]
  [nek]
    type = TransientMultiApp
    input_files = 'nek.i'
    sub_cycling = true
    execute_on = timestep_end
  []
[]

[Transfers]
  [temp_to_openmc]
    type = MultiAppGeneralFieldNearestLocationTransfer
    from_multi_app = nek
    variable = temp
    source_variable = temp
  []
  [power_to_nek]
    type = MultiAppGeneralFieldNearestLocationTransfer
    to_multi_app = nek
    source_variable = kappa_fission
    variable = heat_source
  []
  [power_integral_to_nek]
    type = MultiAppPostprocessorTransfer
    to_postprocessor = source_integral
    from_postprocessor = power
    to_multi_app = nek
  []
  [synchronize_in]
    type = MultiAppPostprocessorTransfer
    to_postprocessor = transfer_in
    from_postprocessor = synchronize
    to_multi_app = nek
  []
[]

[Postprocessors]
  [power]
    type = ElementIntegralVariablePostprocessor
    variable = kappa_fission
  []
  [k]
    type = KEigenvalue
  []
  [k_std_dev]
    type = KStandardDeviation
  []
  [max_tally_err]
    type = TallyRelativeError
  []
  [max_T]
    type = ElementExtremeValue
    variable = temp
  []
  [avg_T]
    type = ElementAverageValue
    variable = temp
  []
  [max_q]
    type = ElementExtremeValue
    variable = kappa_fission
  []
  [synchronize]
    type = Receiver
    default = 1.0
  []
[]

t_nek = ${fparse 2e-4 * 7.669}

[Executioner]
  type = Transient
  dt = ${fparse 2000 * t_nek}
[]

[Outputs]
  exodus = true
  csv = true
  hide = 'synchronize'
[]

(tutorials/gas_compact_multiphysics/openmc_thm.i)

# This input file runs coupled OpenMC Monte Carlo transport, MOOSE heat
# conduction, and THM fluid flow and heat transfer.
# This input should be run with:
#
# cardinal-opt -i common_input.i openmc_thm.i

num_layers_for_THM = 150
num_layers = 50
density_blocks = 'coolant'
temperature_blocks = 'graphite compacts compacts_trimmer_tri'
fuel_blocks = 'compacts compacts_trimmer_tri'

unit_cell_power = ${fparse power / (n_bundles * n_coolant_channels_per_block) * unit_cell_height / height}

[Mesh]
  [solid]
    type = FileMeshGenerator
    file = solid_mesh_in.e
  []
[]

[AuxVariables]
  [cell_temperature]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_density]
    family = MONOMIAL
    order = CONSTANT
  []
  [thm_temp_wall]
    family = MONOMIAL
    order = CONSTANT
    block = ${density_blocks}
  []
  [flux]
  []
[]

[AuxKernels]
  [cell_temperature]
    type = CellTemperatureAux
    variable = cell_temperature
  []
  [cell_density]
    type = CellDensityAux
    variable = cell_density
  []
  [density]
    type = FluidDensityAux
    variable = density
    p = ${outlet_P}
    T = thm_temp
    fp = helium
    execute_on = 'timestep_begin linear'
  []
[]

[FluidProperties]
  [helium]
    type = IdealGasFluidProperties
    molar_mass = 4e-3
    gamma = 1.668282 # should correspond to  Cp = 5189 J/kg/K
    k = 0.2556
    mu = 3.22639e-5
  []
[]

[ICs]
  [fluid_temp_wall]
    type = FunctionIC
    variable = thm_temp_wall
    function = temp_ic
  []
  [fluid_temp]
    type = FunctionIC
    variable = thm_temp
    function = temp_ic
  []
  [heat_source]
    type = ConstantIC
    variable = heat_source
    block = ${fuel_blocks}
    value = ${fparse unit_cell_power / (2.0 * pi * compact_diameter * compact_diameter / 4.0 * unit_cell_height)}
  []
[]

[Functions]
  [temp_ic]
    type = ParsedFunction
    expression = '${inlet_T} + z / ${unit_cell_height} * ${unit_cell_power} / (${mdot} / ${n_bundles} / ${n_coolant_channels_per_block}) / ${fluid_Cp}'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem

  power = ${unit_cell_power}
  scaling = 100.0
  density_blocks = ${density_blocks}
  cell_level = 1

  relaxation = robbins_monro

  temperature_variables = 'solid_temp; thm_temp'
  temperature_blocks = '${temperature_blocks}; ${density_blocks}'

  k_trigger = std_dev
  k_trigger_threshold = 7.5e-4
  batches = 40
  max_batches = 100
  batch_interval = 5

  [Tallies]
    [heat_source]
      type = CellTally
      blocks = ${fuel_blocks}
      name = heat_source

      check_equal_mapped_tally_volumes = true

      trigger = rel_err
      trigger_threshold = 1e-2

      output = 'unrelaxed_tally_std_dev'
    []
  []
[]

[Executioner]
  type = Transient

  # We use a fairly loose tolerance here for a tutorial; you may consider increasing this
  # for production runs
  steady_state_detection = true
  check_aux = true
  steady_state_tolerance = 5e-3
[]

[MultiApps]
  [bison]
    type = TransientMultiApp
    input_files = 'solid_thm.i'
    execute_on = timestep_begin
  []
  [thm]
    type = FullSolveMultiApp
    input_files = 'thm.i'
    execute_on = timestep_end
    max_procs_per_app = 1
    bounding_box_padding = '0.1 0.1 0'
  []
[]

[Transfers]
  [solid_temp_to_openmc]
    type = MultiAppGeometricInterpolationTransfer
    source_variable = T
    variable = solid_temp
    from_multi_app = bison
  []
  [heat_flux_to_openmc]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = flux
    variable = flux
    from_multi_app = bison
    from_boundaries = 'fluid_solid_interface'
    to_boundaries = 'fluid_solid_interface'
    from_postprocessors_to_be_preserved = flux_integral
    to_postprocessors_to_be_preserved = flux_integral
  []
  [source_to_bison]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = heat_source
    variable = power
    to_multi_app = bison
    from_postprocessors_to_be_preserved = heat_source
    to_postprocessors_to_be_preserved = power
  []
  [thm_temp_to_bison]
    type = MultiAppGeometricInterpolationTransfer
    source_variable = thm_temp_wall
    variable = fluid_temp
    to_multi_app = bison
  []

  [q_wall_to_thm]
    type = MultiAppGeneralFieldUserObjectTransfer
    variable = q_wall
    to_multi_app = thm
    source_user_object = q_wall_avg
  []
  [T_wall_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = T_wall
    from_multi_app = thm
    variable = thm_temp_wall
  []
  [T_bulk_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = T
    from_multi_app = thm
    variable = thm_temp
  []
[]

[Postprocessors]
  [flux_integral]
    type = SideIntegralVariablePostprocessor
    variable = flux
    boundary = 'fluid_solid_interface'
    execute_on = 'transfer'
  []
  [heat_source]
    type = ElementIntegralVariablePostprocessor
    variable = heat_source
    execute_on = 'transfer initial timestep_end'
  []
  [max_tally_err]
    type = TallyRelativeError
    value_type = max
  []
  [k]
    type = KEigenvalue
  []
  [k_std_dev]
    type = KStandardDeviation
  []
  [min_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = min
    block = ${fuel_blocks}
  []
  [max_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = max
    block = ${fuel_blocks}
  []
[]


[AuxVariables]
  [q_wall]
  []
[]

[AuxKernels]
  [q_wall]
    type = SpatialUserObjectAux
    variable = q_wall
    user_object = q_wall_avg
  []
[]

[UserObjects]
  [q_wall_avg]
    type = LayeredSideAverage
    boundary = fluid_solid_interface
    variable = flux

    # Note: make this to match the num_elems in the channel
    direction = z
    num_layers = ${num_layers_for_THM}

    direction_min = 0.0
    direction_max = ${unit_cell_height}
  []
  [average_power_axial]
    type = LayeredAverage
    variable = heat_source
    direction = z
    num_layers = ${num_layers}
    block = ${fuel_blocks}
  []
[]

[VectorPostprocessors]
  [power_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_power_axial
  []
[]

[Outputs]
  exodus = true

  [csv]
    type = CSV
    file_base = 'csv_thm/openmc_thm'
  []
[]

(tutorials/gas_assembly/openmc.i)

num_layers_for_THM = 50      # number of elements in the THM model; for the converged
                             # case, we set this to 150

[Mesh]
  # mesh mirror for the solid regions
  [solid]
    type = FileMeshGenerator
    file = solid_mesh_in.e
  []

  # create a mesh for a single coolant channel; because we will receive uniform
  # temperatures and densities from THM on each x-y plane, we can use a very coarse
  # mesh in the radial direction
  [coolant_face]
    type = AnnularMeshGenerator
    nr = 1
    nt = 8
    rmin = 0.0
    rmax = ${fparse channel_diameter / 2.0}
  []
  [extrude]
    type = AdvancedExtruderGenerator
    input = coolant_face
    num_layers = ${num_layers_for_THM}
    direction = '0 0 1'
    heights = '${height}'
    top_boundary = '300' # inlet
    bottom_boundary = '400' # outlet
  []
  [rename]
    type = RenameBlockGenerator
    input = extrude
    old_block = '1'
    new_block = '101'
  []

  # repeat the coolant channels and then combine together to get a combined mesh mirror
  [repeat]
    type = CombinerGenerator
    inputs = rename
    positions_file = coolant_channel_positions.txt
  []
  [add]
    type = CombinerGenerator
    inputs = 'solid repeat'
  []
[]

[AuxVariables]
  [material_id]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_temperature]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_density]
    family = MONOMIAL
    order = CONSTANT
  []
  [thm_temp_wall]
    block = '101'
  []
  [flux]
  []

  # just for postprocessing purposes
  [thm_pressure]
    block = '101'
  []
  [thm_velocity]
    block = '101'
  []
  [z]
    family = MONOMIAL
    order = CONSTANT
    block = 'compacts'
  []
[]

[AuxKernels]
  [material_id]
    type = CellMaterialIDAux
    variable = material_id
  []
  [cell_temperature]
    type = CellTemperatureAux
    variable = cell_temperature
  []
  [cell_density]
    type = CellDensityAux
    variable = cell_density
  []
  [density]
    type = FluidDensityAux
    variable = density
    p = ${outlet_P}
    T = thm_temp
    fp = helium
    execute_on = 'timestep_begin linear'
  []
  [z]
    type = ParsedAux
    variable = z
    use_xyzt = true
    expression = 'z'
  []
[]

[ICs]
  [fluid_temp_wall]
    type = FunctionIC
    variable = thm_temp_wall
    function = temp_ic
  []
  [fluid_temp]
    type = FunctionIC
    variable = thm_temp
    function = temp_ic
  []
  [heat_source]
    type = ConstantIC
    variable = heat_source
    block = 'compacts'
    value = ${fparse power / (n_bundles * n_fuel_compacts_per_block) / (pi * compact_diameter * compact_diameter / 4.0 * height)}
  []
[]

[Functions]
  [temp_ic]
    type = ParsedFunction
    expression = '${inlet_T} + (${height} - z) / ${height} * ${power} / ${mdot} / ${fluid_Cp}'
  []
[]

[FluidProperties]
  [helium]
    type = IdealGasFluidProperties
    molar_mass = 4e-3
    gamma = 1.668282 # should correspond to  Cp = 5189 J/kg/K
    k = 0.2556
    mu = 3.22639e-5
  []
[]

[Problem]
  type = OpenMCCellAverageProblem

  identical_cell_fills = '2'

  power = ${fparse power / n_bundles}
  scaling = 100.0
  cell_level = 1

  relaxation = constant
  relaxation_factor = 0.5

  # to get a faster-running tutorial, we use only 1000 particles per batch; converged
  # results are instead obtained by increasing this parameter to 10000. We also use fewer
  # batches to speed things up; the converged results were obtained with 500 inactive batches
  # and 2000 active batches
  particles = 1000
  inactive_batches = 200
  batches = 1000

  # we will read temperature from THM (for the fluid) and MOOSE (for the solid)
  # into variables we name as 'solid_temp' and 'thm_temp'. This syntax will automatically
  # create those variabes for us
  temperature_variables = 'solid_temp; thm_temp'
  temperature_blocks =    '1 2 4;      101'
  density_blocks = '101'

  [Tallies]
    [heat_source]
      type = CellTally
      blocks = '2'
      name = heat_source
      check_equal_mapped_tally_volumes = true
      output = 'unrelaxed_tally_std_dev'
    []
  []
[]

[MultiApps]
  [bison]
    type = TransientMultiApp
    input_files = 'solid.i'
    execute_on = timestep_begin
  []
  [thm]
    type = FullSolveMultiApp
    input_files = 'thm.i'
    execute_on = timestep_end
    max_procs_per_app = 1
    bounding_box_padding = '0.1 0.1 0'
    positions_file = coolant_channel_positions.txt
    output_in_position = true
  []
[]

[Transfers]
  [solid_temp_to_openmc]
    type = MultiAppGeometricInterpolationTransfer
    source_variable = T
    variable = solid_temp
    from_multi_app = bison
  []
  [heat_flux_to_openmc]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = flux
    variable = flux
    from_multi_app = bison
    from_boundaries = 'fluid_solid_interface'
    to_boundaries = 'fluid_solid_interface'
    from_postprocessors_to_be_preserved = flux_integral
    to_postprocessors_to_be_preserved = flux_integral
  []
  [source_to_bison]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = heat_source
    variable = power
    to_multi_app = bison
    from_postprocessors_to_be_preserved = heat_source
    to_postprocessors_to_be_preserved = power
  []
  [thm_temp_to_bison]
    type = MultiAppGeometricInterpolationTransfer
    source_variable = thm_temp_wall
    variable = thm_temp
    to_multi_app = bison
  []

  [q_wall_to_thm]
    type = MultiAppGeneralFieldUserObjectTransfer
    variable = q_wall
    to_multi_app = thm
    source_user_object = q_wall_avg
  []
  [T_wall_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = T_wall
    from_multi_app = thm
    variable = thm_temp_wall
    to_boundaries = 'fluid_solid_interface'
  []
  [T_bulk_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = T
    from_multi_app = thm
    variable = thm_temp
  []

  # just for postprocessing purposes
  [pressure_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = p
    from_multi_app = thm
    variable = thm_pressure
  []
  [velocity_from_thm]
    type = MultiAppGeneralFieldNearestLocationTransfer
    source_variable = vel_z
    from_multi_app = thm
    variable = thm_velocity
  []
[]

[UserObjects]
  [q_wall_avg]
    type = NearestPointLayeredSideAverage
    boundary = 'fluid_solid_interface'
    variable = flux

    # Note: make this to match the num_elems in the channel
    direction = z
    num_layers = ${num_layers_for_THM}
    points_file = coolant_channel_positions.txt

    direction_min = 0.0
    direction_max = ${height}
  []
  [average_power_axial]
    type = LayeredAverage
    variable = heat_source
    direction = z
    num_layers = ${num_layers_for_plots}
    block = 'compacts'
  []
  [average_fluid_axial]
    type = LayeredAverage
    variable = thm_temp
    direction = z
    num_layers = ${num_layers_for_plots}
    block = '101'
  []
  [average_pressure]
    type = LayeredAverage
    variable = thm_pressure
    direction = z
    num_layers = ${num_layers_for_plots}
    block = '101'
  []
  [average_axial_velocity]
    type = LayeredAverage
    variable = thm_velocity
    direction = z
    num_layers = ${num_layers_for_plots}
    block = '101'
  []
[]

[VectorPostprocessors]
  [power_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_power_axial
  []
  [fluid_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_fluid_axial
  []
  [pressure_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_pressure
  []
  [velocity_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_axial_velocity
  []
[]

[Postprocessors]
  [flux_integral]
    type = SideIntegralVariablePostprocessor
    variable = flux
    boundary = 'fluid_solid_interface'
    execute_on = 'transfer linear'
  []
  [heat_source]
    type = ElementIntegralVariablePostprocessor
    variable = heat_source
    execute_on = 'transfer initial timestep_end'
  []
  [max_tally_rel_err]
    type = TallyRelativeError
    value_type = max
  []
  [k]
    type = KEigenvalue
  []
  [k_std_dev]
    type = KStandardDeviation
  []
  [min_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = min
    block = 'compacts'
  []
  [max_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = max
    block = 'compacts'
  []
  [z_max_power]
    type = ElementExtremeValue
    proxy_variable = heat_source
    variable = z
    block = 'compacts'
  []
  [max_Tf]
    type = ElementExtremeValue
    variable = thm_temp
    block = '101'
  []
  [P_in]
    type = SideAverageValue
    variable = thm_pressure
    boundary = '300'
  []
  [pressure_drop]
    type = LinearCombinationPostprocessor
    pp_names = 'P_in'
    pp_coefs = '1.0'
    b = '${fparse -outlet_P}'
  []
[]

[Executioner]
  type = Transient
  num_steps = 10
[]

[Outputs]
  exodus = true
  csv = true
  hide = 'P_in flux_integral z'
[]

(tutorials/pincell_multiphysics/openmc.i)

inlet_T  = 573.0           # inlet temperature
power = 1e3                # total power (W)
Re = 500.0                 # Reynolds number
outlet_P = 1e6

height = 0.5               # total height of the domain
Df = 0.825e-2              # fuel diameter
pin_diameter = 0.97e-2     # pin outer diameter
pin_pitch = 1.28e-2        # pin pitch

mu = 8.8e-5                # fluid dynamic viscosity
rho = 723.6                # fluid density
Cp = 5512.0                # fluid isobaric specific heat capacity

Rf = ${fparse Df / 2.0}

flow_area = ${fparse pin_pitch * pin_pitch - pi * pin_diameter * pin_diameter / 4.0}
wetted_perimeter = ${fparse pi * pin_diameter}
hydraulic_diameter = ${fparse 4.0 * flow_area / wetted_perimeter}

U_ref = ${fparse Re * mu / rho / hydraulic_diameter}
mdot = ${fparse rho * U_ref * flow_area}
dT = ${fparse power / mdot / Cp}

[Mesh]
  [solid]
    type = FileMeshGenerator
    file = solid_in.e
  []
[]

[AuxVariables]
# These auxiliary variables are all just for visualizing the solution and
# the mapping - none of these are part of the calculation sequence

  [material_id]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_temperature]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_density]
    family = MONOMIAL
    order = CONSTANT
  []
[]

[AuxKernels]
  [material_id]
    type = CellMaterialIDAux
    variable = material_id
  []
  [cell_temperature]
    type = CellTemperatureAux
    variable = cell_temperature
  []
  [cell_density]
    type = CellDensityAux
    variable = cell_density
  []
  [density]
    type = FluidDensityAux
    variable = density
    p = ${outlet_P}
    T = nek_temp
    fp = sodium
    execute_on = 'INITIAL TIMESTEP_END'
  []
[]

[FluidProperties]
  [sodium]
    type = SodiumSaturationFluidProperties
  []
[]

[ICs]
  [nek_temp]
    type = FunctionIC
    variable = nek_temp
    function = temp_ic
  []
  [solid_temp]
    type = FunctionIC
    variable = solid_temp
    function = temp_ic
  []
  [heat_source]
    type = ConstantIC
    variable = heat_source
    block = '2'
    value = ${fparse power / (pi * Rf * Rf * height)}
  []
[]

[Functions]
  [temp_ic]
    type = ParsedFunction
    expression = '${inlet_T} + z / ${height} * ${dT}'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem

  power = ${power}
  scaling = 100.0
  density_blocks = '1'
  cell_level = 0

  # This automatically creates these variables and will read from the non-default choice of 'temp'
  temperature_variables = 'solid_temp; nek_temp'
  temperature_blocks    = '2 3;        1'

  relaxation = robbins_monro

  # Set some parameters for when we terminate the OpenMC solve in each iteration;
  # this will run a minimum of 30 batches, and after that, terminate once reaching
  # the specified std. dev. of k and rel. err. of the fission tally
  inactive_batches = 20
  batches = 30
  k_trigger = std_dev
  k_trigger_threshold = 7.5e-4
  batch_interval = 50
  max_batches = 1000

  [Tallies]
    [heat_source]
      type = CellTally
      blocks = '2'
      name = heat_source

      check_equal_mapped_tally_volumes = true

      trigger = rel_err
      trigger_threshold = 2e-2
      output = unrelaxed_tally_std_dev
    []
  []
[]

[MultiApps]
  [bison]
    type = TransientMultiApp
    input_files = 'bison.i'
    execute_on = timestep_begin
    sub_cycling = true
  []
[]

[Transfers]
  [solid_temp_to_openmc]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = T
    variable = solid_temp
    from_multi_app = bison
  []
  [source_to_bison]
    type = MultiAppCopyTransfer
    source_variable = heat_source
    variable = power
    to_multi_app = bison
  []
  [temp_from_nek]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = nek_temp
    from_multi_app = bison
    variable = nek_temp
  []
[]

[Outputs]
  exodus = true
  csv = true
[]

[Executioner]
  type = Transient
  dt = 0.5
  num_steps = 10
[]

[Postprocessors]
  [max_tally_rel_err]
    type = TallyRelativeError
    value_type = max
  []
  [k]
    type = KEigenvalue
  []
  [k_std_dev]
    type = KStandardDeviation
  []
[]

(tutorials/gas_compact_multiphysics/openmc_nek.i)

# This input file runs coupled OpenMC Monte Carlo transport, MOOSE heat
# conduction, and NekRS fluid flow and heat transfer.
# This input should be run with:
#
# cardinal-opt -i common_input.i openmc_nek.i

num_layers_for_THM = 150
density_blocks = 'coolant'
temperature_blocks = 'graphite compacts compacts_trimmer_tri'
fuel_blocks = 'compacts compacts_trimmer_tri'

unit_cell_power = ${fparse power / (n_bundles * n_coolant_channels_per_block) * unit_cell_height / height}

U_ref = ${fparse mdot / (n_bundles * n_coolant_channels_per_block) / fluid_density / (pi * channel_diameter * channel_diameter / 4.0)}
t0 = ${fparse channel_diameter / U_ref}
nek_dt = 6e-3
N = 1000

[Mesh]
  [solid]
    type = FileMeshGenerator
    file = solid_mesh_in.e
  []
[]

[AuxVariables]
  [cell_temperature]
    family = MONOMIAL
    order = CONSTANT
  []
  [cell_density]
    family = MONOMIAL
    order = CONSTANT
  []
[]

[AuxKernels]
  [cell_temperature]
    type = CellTemperatureAux
    variable = cell_temperature
  []
  [cell_density]
    type = CellDensityAux
    variable = cell_density
  []
  [density]
    type = FluidDensityAux
    variable = density
    p = ${outlet_P}
    T = nek_temp
    fp = helium
    execute_on = 'timestep_begin'
  []
[]

[FluidProperties]
  [helium]
    type = IdealGasFluidProperties
    molar_mass = 4e-3
    gamma = 1.668282 # should correspond to  Cp = 5189 J/kg/K
    k = 0.2556
    mu = 3.22639e-5
  []
[]

[ICs]
  [temp]
    type = FunctionIC
    variable = nek_temp
    function = temp_ic
  []
  [solid_temp]
    type = FunctionIC
    variable = solid_temp
    function = temp_ic
  []
[]

[Functions]
  [temp_ic]
    type = ParsedFunction
    expression = '${inlet_T} + z / ${unit_cell_height} * ${unit_cell_power} / (${mdot} / ${n_bundles} / ${n_coolant_channels_per_block}) / ${fluid_Cp}'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem

  power = ${unit_cell_power}
  scaling = 100.0
  density_blocks = ${density_blocks}
  cell_level = 1

  relaxation = robbins_monro

  temperature_variables = 'solid_temp;   nek_temp'
  temperature_blocks = '${temperature_blocks}; ${density_blocks}'

  k_trigger = std_dev
  k_trigger_threshold = 7.5e-4
  batches = 40
  max_batches = 100
  batch_interval = 5

  [Tallies]
    [heat_source]
      type = CellTally
      blocks = ${fuel_blocks}
      name = heat_source

      check_equal_mapped_tally_volumes = true

      trigger = rel_err
      trigger_threshold = 1e-2

      output = 'unrelaxed_tally_std_dev'
    []
  []
[]

[Executioner]
  type = Transient
  dt = ${fparse N * nek_dt * t0}

  # This is somewhat loose, and you should use a tighter tolerance for production runs;
  # we use 1e-2 to obtain a faster tutorial
  steady_state_detection = true
  check_aux = true
  steady_state_tolerance = 1e-2
[]

[MultiApps]
  [bison]
    type = TransientMultiApp
    input_files = 'solid_nek.i'
    execute_on = timestep_end
    sub_cycling = true
  []
[]

[Transfers]
  [solid_temp_to_openmc]
    type = MultiAppGeometricInterpolationTransfer
    source_variable = T
    variable = solid_temp
    from_multi_app = bison
  []
  [source_to_bison]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = heat_source
    variable = power
    to_multi_app = bison
    from_postprocessors_to_be_preserved = heat_source
    to_postprocessors_to_be_preserved = power
  []
  [temp_from_nek]
    type = MultiAppGeneralFieldShapeEvaluationTransfer
    source_variable = nek_bulk_temp
    from_multi_app = bison
    variable = nek_temp
  []
[]

[Postprocessors]
  [heat_source]
    type = ElementIntegralVariablePostprocessor
    variable = heat_source
    execute_on = 'transfer initial timestep_end'
  []
  [max_tally_err]
    type = TallyRelativeError
    value_type = max
  []
  [k]
    type = KEigenvalue
  []
  [k_std_dev]
    type = KStandardDeviation
  []
  [min_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = min
    block = ${fuel_blocks}
  []
  [max_power]
    type = ElementExtremeValue
    variable = heat_source
    value_type = max
    block = ${fuel_blocks}
  []
[]

[UserObjects]
  [average_power_axial]
    type = LayeredAverage
    variable = heat_source
    direction = z
    num_layers = ${num_layers_for_plots}
    block = ${fuel_blocks}
  []
[]

[VectorPostprocessors]
  [power_avg]
    type = SpatialUserObjectVectorPostprocessor
    userobject = average_power_axial
  []
[]

[Outputs]
  [out]
    type = Exodus
    hide = 'solid_temp nek_temp'
  []

  [csv]
    type = CSV
    file_base = 'csv_nek/openmc_nek'
  []
[]

(test/tests/postprocessors/eigenvalue/openmc.i)

[Mesh]
  [sphere]
    type = FileMeshGenerator
    file = ../../neutronics/meshes/sphere.e
  []
  [solid]
    type = CombinerGenerator
    inputs = sphere
    positions = '0 0 0
                 0 0 4
                 0 0 8'
  []
  [solid_ids]
    type = SubdomainIDGenerator
    input = solid
    subdomain_id = '100'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem
  power = 100.0
  temperature_blocks = '100'
  cell_level = 0
  check_tally_sum = false

  initial_properties = xml

  [Tallies]
    [Cell]
      type = CellTally
      blocks = '100'
    []
  []
[]

[Executioner]
  type = Transient
  num_steps = 1
[]

[Postprocessors]
  [k_collision]
    type = KEigenvalue
    value_type = 'collision'
  []
  [k_absorption]
    type = KEigenvalue
    value_type = 'absorption'
  []
  [k_tracklength]
    type = KEigenvalue
    value_type = 'tracklength'
  []
  [k_combined]
    type = KEigenvalue
    value_type = 'combined'
  []
  [k_collision_std_dev]
    type = KStandardDeviation
    value_type = 'collision'
  []
  [k_absorption_std_dev]
    type = KStandardDeviation
    value_type = 'absorption'
  []
  [k_tracklength_std_dev]
    type = KStandardDeviation
    value_type = 'tracklength'
  []
  [k_combined_std_dev]
    type = KStandardDeviation
    value_type = 'combined'
  []
[]

[Outputs]
  csv = true
[]

(test/tests/neutronics/triggers/k_std_dev.i)

[Mesh]
  [sphere]
    type = FileMeshGenerator
    file = ../meshes/sphere.e
  []
  [solid]
    type = CombinerGenerator
    inputs = sphere
    positions = '0 0 0
                 0 0 4
                 0 0 8'
  []
  [solid_ids]
    type = SubdomainIDGenerator
    input = solid
    subdomain_id = '100'
  []
[]

[Problem]
  type = OpenMCCellAverageProblem

  k_trigger = std_dev
  k_trigger_threshold = 1.2e-2
  max_batches = 100
[]

[Executioner]
  type = Transient
  num_steps = 1
[]

[Postprocessors]
  [k_std_dev]
    type = KStandardDeviation
  []
[]

[Outputs]
  csv = true
[]

Description
Example Input Syntax
Input Parameters
Input Files