ParkinCoulterDPAUserObject

This userobject computes the displacement per atoms caused by neutron irradiation for displacement functions computed by a Parkin-Coulter displacement function. In these MOOSE Background information on DPA calculation can be found here.

Example Input File Syntax

#
# This test follows the Huang & Ghoniem "Neutron displacement damage cross sections for SiC"
# J. of Nucl. Mat. 199, (1993), 221-230
#
[Mesh<<<{"href": "../../syntax/Mesh/index.html"}>>>]
 type = GeneratedMesh
 dim = 1
 xmin = 0
 xmax = 1
 nx = 2
[]

[Problem<<<{"href": "../../syntax/Problem/index.html"}>>>]
  type = FEProblem
  kernel_coverage_check = false
[]

[Variables<<<{"href": "../../syntax/Variables/index.html"}>>>]
  [./test_var]
  [../]
[]

[Functions<<<{"href": "../../syntax/Functions/index.html"}>>>]
  [./HG_SiSi]
    type = PiecewiseLinear<<<{"description": "Linearly interpolates between pairs of x-y data", "href": "../functions/PiecewiseLinear.html"}>>>
    data_file<<<{"description": "File holding CSV data"}>>> = 'HG_SiSi.csv'
    format<<<{"description": "Format of csv data file that is in either in columns or rows"}>>> = columns
  [../]

  [./HG_SiC]
    type = PiecewiseLinear<<<{"description": "Linearly interpolates between pairs of x-y data", "href": "../functions/PiecewiseLinear.html"}>>>
    data_file<<<{"description": "File holding CSV data"}>>> = 'HG_SiC.csv'
    format<<<{"description": "Format of csv data file that is in either in columns or rows"}>>> = columns
  [../]

  [./HG_CSi]
    type = PiecewiseLinear<<<{"description": "Linearly interpolates between pairs of x-y data", "href": "../functions/PiecewiseLinear.html"}>>>
    data_file<<<{"description": "File holding CSV data"}>>> = 'HG_CSi.csv'
    format<<<{"description": "Format of csv data file that is in either in columns or rows"}>>> = columns
  [../]

  [./HG_CC]
    type = PiecewiseLinear<<<{"description": "Linearly interpolates between pairs of x-y data", "href": "../functions/PiecewiseLinear.html"}>>>
    data_file<<<{"description": "File holding CSV data"}>>> = 'HG_CC.csv'
    format<<<{"description": "Format of csv data file that is in either in columns or rows"}>>> = columns
  [../]
[]

[UserObjects<<<{"href": "../../syntax/UserObjects/index.html"}>>>]
  [./parkin_coulter]
     type = ParkinCoulterDPAUserObject<<<{"description": "Computes the dose in dpa from composition, cross section, damage type, and neutron flux for polyatomic materials using Parkin-Coulter's method.", "href": "ParkinCoulterDPAUserObject.html"}>>>
     damage_reaction_types<<<{"description": "The neutron reaction causing radiation damage"}>>> = 'elastic inelastic'
     irradiation_time<<<{"description": "Irradiation time used "}>>> = 1

     Z<<<{"description": "The atomic numbers of all present isotopes"}>>> = '6 14'
     A<<<{"description": "The mass numbers of all present isotopes"}>>> = '12 28'
     number_densities<<<{"description": "The number densities of all present isotopes"}>>> = '0.5 0.5'
     scalar_flux<<<{"description": "The values of the neutron scalar flux by energy group starting with the highest energy group"}>>> = '0.048138819 0.16809268 0.142519665 0.122144812 0.104682829
                    0.08971709 0.04904444 0.04213553 0.233524136'
     energy_group_boundaries<<<{"description": "The neutron flux energy group boundaries in units of eV starting with the highest energy group"}>>> = '3.455e6 1e6 1e5 1e4 1e3 1e2 10.0 2.4 0.625 1e-5'
     cross_section<<<{"description": "The values of the cross sections. Each semicolon separated vector contains cross sections for a particular nuclide and reaction type. Each entry must be number of energy groups entries long. One vector must be provided for each nuclide/reaction type combination. The ordering is as follows: if there are reaction typesa and b, and nuclides i, k, and l, the ordering will be xs_ai; xs_ak; xs_al; xs_bi; xs_bk, xs_bl"}>>> = '2.136 3.7 4.622 4.737 4.748 4.75 4.75 4.757 13.198;
                      2.938 4.205 1.980 1.918 1.952 1.956 1.957 1.959 4.034;
                      0     0     0     0     0     0     0     0     0;
                      0.10848 0   0     0     0     0     0     0     0'
     Q<<<{"description": "The Q values by reaction type and then isotope. Assumed zero if not provided."}>>> = '0 0; 0 -1.779e+6'

     displacement_thresholds<<<{"description": "Dispacement thresholds"}>>> = '16.3 92.6'
     logarithmic_energy_spacing<<<{"description": "Spacing of the energy points En in log space energy_spacing = E_{n+1} / En"}>>> = 1.25
  [../]

  [./huang_ghoniem_CSV]
     type = FunctionDPAUserObject<<<{"description": "Computes the dose in dpa from composition, cross section, damage type, and neutron flux. The damage functions are provided as MOOSE functions where energy is provided via the time arg slot.", "href": "FunctionDPAUserObject.html"}>>>
     damage_reaction_types<<<{"description": "The neutron reaction causing radiation damage"}>>> = 'elastic inelastic'
     damage_functions<<<{"description": "Damage functions for each combinations of projectiles and targets."}>>> = 'HG_CC HG_CSi; HG_SiC HG_SiSi'
     irradiation_time<<<{"description": "Irradiation time used "}>>> = 1

     Z<<<{"description": "The atomic numbers of all present isotopes"}>>> = '6 14'
     A<<<{"description": "The mass numbers of all present isotopes"}>>> = '12 28'
     number_densities<<<{"description": "The number densities of all present isotopes"}>>> = '0.5 0.5'
     scalar_flux<<<{"description": "The values of the neutron scalar flux by energy group starting with the highest energy group"}>>> = '0.048138819 0.16809268 0.142519665 0.122144812 0.104682829
                    0.08971709 0.04904444 0.04213553 0.233524136'
     energy_group_boundaries<<<{"description": "The neutron flux energy group boundaries in units of eV starting with the highest energy group"}>>> = '3.455e6 1e6 1e5 1e4 1e3 1e2 10.0 2.4 0.625 1e-5'
     cross_section<<<{"description": "The values of the cross sections. Each semicolon separated vector contains cross sections for a particular nuclide and reaction type. Each entry must be number of energy groups entries long. One vector must be provided for each nuclide/reaction type combination. The ordering is as follows: if there are reaction typesa and b, and nuclides i, k, and l, the ordering will be xs_ai; xs_ak; xs_al; xs_bi; xs_bk, xs_bl"}>>> = '2.136 3.7 4.622 4.737 4.748 4.75 4.75 4.757 13.198;
                      2.938 4.205 1.980 1.918 1.952 1.956 1.957 1.959 4.034;
                      0     0     0     0     0     0     0     0     0;
                      0.10848 0   0     0     0     0     0     0     0'
     Q<<<{"description": "The Q values by reaction type and then isotope. Assumed zero if not provided."}>>> = '0 0; 0 -1.779e+6'
  [../]
[]

[Postprocessors<<<{"href": "../../syntax/Postprocessors/index.html"}>>>]
  [./dpa_from_function]
    type = DPAPostprocessor<<<{"description": "Retrieves the value of the dpa from a DPAUserObjectBase.", "href": "../postprocessors/DPAPostprocessor.html"}>>>
    dpa_object<<<{"description": "The neutronics damage object."}>>> = huang_ghoniem_CSV
  [../]

  [./dpa_from_parkin_coulter]
    type = DPAPostprocessor<<<{"description": "Retrieves the value of the dpa from a DPAUserObjectBase.", "href": "../postprocessors/DPAPostprocessor.html"}>>>
    dpa_object<<<{"description": "The neutronics damage object."}>>> = parkin_coulter
  [../]
[]

[Executioner<<<{"href": "../../syntax/Executioner/index.html"}>>>]
  type = Steady
[]

[Outputs<<<{"href": "../../syntax/Outputs/index.html"}>>>]
  csv<<<{"description": "Output the scalar variable and postprocessors to a *.csv file using the default CSV output."}>>> = true
[]
(tests/userobjects/dpa/huang_ghoniem_92.i)

Computes the dose in dpa from composition, cross section, damage type, and neutron flux for polyatomic materials using Parkin-Coulter's method.

Input Parameters

  • displacement_thresholdsDispacement thresholds

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

    Unit:(no unit assumed)

    Controllable:No

    Description:Dispacement thresholds

  • logarithmic_energy_spacingSpacing of the energy points En in log space energy_spacing = E_{n+1} / En

    C++ Type:double

    Unit:(no unit assumed)

    Controllable:No

    Description:Spacing of the energy points En in log space energy_spacing = E_{n+1} / En

Required Parameters

  • AThe mass numbers of all present isotopes

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The mass numbers of all present isotopes

  • EcapCapture energy Ecap_ij of species i being trapped in j site

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

    Unit:(no unit assumed)

    Controllable:No

    Description:Capture energy Ecap_ij of species i being trapped in j site

  • QThe Q values by reaction type and then isotope. Assumed zero if not provided.

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The Q values by reaction type and then isotope. Assumed zero if not provided.

  • ZThe atomic numbers of all present isotopes

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The atomic numbers of all present isotopes

  • cross_sectionThe values of the cross sections. Each semicolon separated vector contains cross sections for a particular nuclide and reaction type. Each entry must be number of energy groups entries long. One vector must be provided for each nuclide/reaction type combination. The ordering is as follows: if there are reaction typesa and b, and nuclides i, k, and l, the ordering will be xs_ai; xs_ak; xs_al; xs_bi; xs_bk, xs_bl

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The values of the cross sections. Each semicolon separated vector contains cross sections for a particular nuclide and reaction type. Each entry must be number of energy groups entries long. One vector must be provided for each nuclide/reaction type combination. The ordering is as follows: if there are reaction typesa and b, and nuclides i, k, and l, the ordering will be xs_ai; xs_ak; xs_al; xs_bi; xs_bk, xs_bl

  • damage_reaction_typesThe neutron reaction causing radiation damage

    C++ Type:MultiMooseEnum

    Options:elastic, inelastic

    Controllable:No

    Description:The neutron reaction causing radiation damage

  • energy_group_boundariesThe neutron flux energy group boundaries in units of eV starting with the highest energy group

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The neutron flux energy group boundaries in units of eV starting with the highest energy group

  • irradiation_timeIrradiation time used

    C++ Type:double

    Unit:(no unit assumed)

    Controllable:No

    Description:Irradiation time used

  • lattice_binding_energiesLattice binding energies

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

    Unit:(no unit assumed)

    Controllable:No

    Description:Lattice binding energies

  • number_densitiesThe number densities of all present isotopes

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The number densities of all present isotopes

  • scalar_fluxThe values of the neutron scalar flux by energy group starting with the highest energy group

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

    Unit:(no unit assumed)

    Controllable:No

    Description:The values of the neutron scalar flux by energy group starting with the highest energy group

  • uniform_energy_spacing0.25Uniform energy spacing below the threshold

    Default:0.25

    C++ Type:double

    Unit:(no unit assumed)

    Controllable:No

    Description:Uniform energy spacing below the threshold

  • uniform_energy_spacing_threshold10Threshold below which energy points are spaced uniformly.

    Default:10

    C++ Type:double

    Unit:(no unit assumed)

    Controllable:No

    Description:Threshold below which energy points are spaced uniformly.

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).

  • 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

Execution Scheduling Parameters

  • 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.

  • 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

  • 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

    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.

Material Property Retrieval Parameters

Input Files

References

No citations exist within this document.