AFMExchangeStiffnessEnergy

Calculates an integral over the DM interaction free energy density (coupling AFD and magnetic ordering).

Overview

Computes the free energy in the simulation box (volume $var element = document.getElementById("moose-equation-92a82910-9dc5-4909-a6ef-31e38631da46");katex.render("\\Omega", element, {displayMode:false,throwOnError:false,macros:{"\\bs":"\\boldsymbol{#1}","\\normal":"\\bs{n}","\\grad":"\\bs{\\nabla}","\\divergence":"\\grad \\cdot","\\norm":"\\left\\lVert#1\\right\\rVert","\\abs":"\\left\\lvert#1\\right\\rvert","\\tr":"\\text{tr}","\\dev":"\\text{dev}","\\sym":"\\text{sym}","\\diff":"\\text{ d}#1","\\activepart":"{\\left< A \\right>}","\\inactivepart":"{\\left< I \\right>}","\\Gc":"{\\mathcal{G}_c}","\\strain":"\\bs{\\varepsilon}","\\stress":"\\bs{\\sigma}","\\macaulay":"\\left<#1\\right>","\\body":"\\Omega","\\bodyboundary":"{\\partial\\body}","\\ep":"{\\varepsilon^p}","\\ep0":"{\\varepsilon_0^p}","\\epdot":"{\\dot{\\varepsilon}}^p","\\epdot0":"{\\dot{\\varepsilon}}_0^p","\\bfa":"\\boldsymbol{a}","\\bfb":"\\boldsymbol{b}","\\bfc":"\\boldsymbol{c}","\\bfd":"\\boldsymbol{d}","\\bfe":"\\boldsymbol{e}","\\bff":"\\boldsymbol{f}","\\bfg":"\\boldsymbol{g}","\\bfh":"\\boldsymbol{h}","\\bfi":"\\boldsymbol{i}","\\bfj":"\\boldsymbol{j}","\\bfk":"\\boldsymbol{k}","\\bfl":"\\boldsymbol{l}","\\bfm":"\\boldsymbol{m}","\\bfn":"\\boldsymbol{n}","\\bfo":"\\boldsymbol{o}","\\bfp":"\\boldsymbol{p}","\\bfq":"\\boldsymbol{q}","\\bfr":"\\boldsymbol{r}","\\bfs":"\\boldsymbol{s}","\\bft":"\\boldsymbol{t}","\\bfu":"\\boldsymbol{u}","\\bfv":"\\boldsymbol{v}","\\bfw":"\\boldsymbol{w}","\\bfx":"\\boldsymbol{x}","\\bfy":"\\boldsymbol{y}","\\bfz":"\\boldsymbol{z}","\\bfA":"\\boldsymbol{A}","\\bfB":"\\boldsymbol{B}","\\bfC":"\\boldsymbol{C}","\\bfD":"\\boldsymbol{D}","\\bfE":"\\boldsymbol{E}","\\bfF":"\\boldsymbol{F}","\\bfG":"\\boldsymbol{G}","\\bfH":"\\boldsymbol{H}","\\bfI":"\\boldsymbol{I}","\\bfJ":"\\boldsymbol{J}","\\bfK":"\\boldsymbol{K}","\\bfL":"\\boldsymbol{L}","\\bfM":"\\boldsymbol{M}","\\bfN":"\\boldsymbol{N}","\\bfO":"\\boldsymbol{O}","\\bfP":"\\boldsymbol{P}","\\bfQ":"\\boldsymbol{Q}","\\bfR":"\\boldsymbol{R}","\\bfS":"\\boldsymbol{S}","\\bfT":"\\boldsymbol{T}","\\bfU":"\\boldsymbol{U}","\\bfV":"\\boldsymbol{V}","\\bfW":"\\boldsymbol{W}","\\bfX":"\\boldsymbol{X}","\\bfY":"\\boldsymbol{Y}","\\bfZ":"\\boldsymbol{Z}"}});$ ) due to the long-range exchange interactions in the antiferromagnet,

$var element = document.getElementById("moose-equation-3f70e686-38c8-4a4a-be68-adb730798b92");katex.render(" \\begin{aligned} F_\\mathrm{\\nabla L} = \\int\\limits_\\Omega \\left\\{ A_e \\left[\\left(\\nabla L_x\\right)^2 + \\left(\\nabla L_y\\right)^2 \\left(\\nabla L_z\\right)^2\\right] \\right\\}. \\end{aligned}", element, {displayMode:true,throwOnError:false,macros:{"\\bs":"\\boldsymbol{#1}","\\normal":"\\bs{n}","\\grad":"\\bs{\\nabla}","\\divergence":"\\grad \\cdot","\\norm":"\\left\\lVert#1\\right\\rVert","\\abs":"\\left\\lvert#1\\right\\rvert","\\tr":"\\text{tr}","\\dev":"\\text{dev}","\\sym":"\\text{sym}","\\diff":"\\text{ d}#1","\\activepart":"{\\left< A \\right>}","\\inactivepart":"{\\left< I \\right>}","\\Gc":"{\\mathcal{G}_c}","\\strain":"\\bs{\\varepsilon}","\\stress":"\\bs{\\sigma}","\\macaulay":"\\left<#1\\right>","\\body":"\\Omega","\\bodyboundary":"{\\partial\\body}","\\ep":"{\\varepsilon^p}","\\ep0":"{\\varepsilon_0^p}","\\epdot":"{\\dot{\\varepsilon}}^p","\\epdot0":"{\\dot{\\varepsilon}}_0^p","\\bfa":"\\boldsymbol{a}","\\bfb":"\\boldsymbol{b}","\\bfc":"\\boldsymbol{c}","\\bfd":"\\boldsymbol{d}","\\bfe":"\\boldsymbol{e}","\\bff":"\\boldsymbol{f}","\\bfg":"\\boldsymbol{g}","\\bfh":"\\boldsymbol{h}","\\bfi":"\\boldsymbol{i}","\\bfj":"\\boldsymbol{j}","\\bfk":"\\boldsymbol{k}","\\bfl":"\\boldsymbol{l}","\\bfm":"\\boldsymbol{m}","\\bfn":"\\boldsymbol{n}","\\bfo":"\\boldsymbol{o}","\\bfp":"\\boldsymbol{p}","\\bfq":"\\boldsymbol{q}","\\bfr":"\\boldsymbol{r}","\\bfs":"\\boldsymbol{s}","\\bft":"\\boldsymbol{t}","\\bfu":"\\boldsymbol{u}","\\bfv":"\\boldsymbol{v}","\\bfw":"\\boldsymbol{w}","\\bfx":"\\boldsymbol{x}","\\bfy":"\\boldsymbol{y}","\\bfz":"\\boldsymbol{z}","\\bfA":"\\boldsymbol{A}","\\bfB":"\\boldsymbol{B}","\\bfC":"\\boldsymbol{C}","\\bfD":"\\boldsymbol{D}","\\bfE":"\\boldsymbol{E}","\\bfF":"\\boldsymbol{F}","\\bfG":"\\boldsymbol{G}","\\bfH":"\\boldsymbol{H}","\\bfI":"\\boldsymbol{I}","\\bfJ":"\\boldsymbol{J}","\\bfK":"\\boldsymbol{K}","\\bfL":"\\boldsymbol{L}","\\bfM":"\\boldsymbol{M}","\\bfN":"\\boldsymbol{N}","\\bfO":"\\boldsymbol{O}","\\bfP":"\\boldsymbol{P}","\\bfQ":"\\boldsymbol{Q}","\\bfR":"\\boldsymbol{R}","\\bfS":"\\boldsymbol{S}","\\bfT":"\\boldsymbol{T}","\\bfU":"\\boldsymbol{U}","\\bfV":"\\boldsymbol{V}","\\bfW":"\\boldsymbol{W}","\\bfX":"\\boldsymbol{X}","\\bfY":"\\boldsymbol{Y}","\\bfZ":"\\boldsymbol{Z}"}});$

The quantity $var element = document.getElementById("moose-equation-d9788e8c-ce2f-42a8-9109-adc5840ae8c7");katex.render("\\mathbf{L}", element, {displayMode:false,throwOnError:false,macros:{"\\bs":"\\boldsymbol{#1}","\\normal":"\\bs{n}","\\grad":"\\bs{\\nabla}","\\divergence":"\\grad \\cdot","\\norm":"\\left\\lVert#1\\right\\rVert","\\abs":"\\left\\lvert#1\\right\\rvert","\\tr":"\\text{tr}","\\dev":"\\text{dev}","\\sym":"\\text{sym}","\\diff":"\\text{ d}#1","\\activepart":"{\\left< A \\right>}","\\inactivepart":"{\\left< I \\right>}","\\Gc":"{\\mathcal{G}_c}","\\strain":"\\bs{\\varepsilon}","\\stress":"\\bs{\\sigma}","\\macaulay":"\\left<#1\\right>","\\body":"\\Omega","\\bodyboundary":"{\\partial\\body}","\\ep":"{\\varepsilon^p}","\\ep0":"{\\varepsilon_0^p}","\\epdot":"{\\dot{\\varepsilon}}^p","\\epdot0":"{\\dot{\\varepsilon}}_0^p","\\bfa":"\\boldsymbol{a}","\\bfb":"\\boldsymbol{b}","\\bfc":"\\boldsymbol{c}","\\bfd":"\\boldsymbol{d}","\\bfe":"\\boldsymbol{e}","\\bff":"\\boldsymbol{f}","\\bfg":"\\boldsymbol{g}","\\bfh":"\\boldsymbol{h}","\\bfi":"\\boldsymbol{i}","\\bfj":"\\boldsymbol{j}","\\bfk":"\\boldsymbol{k}","\\bfl":"\\boldsymbol{l}","\\bfm":"\\boldsymbol{m}","\\bfn":"\\boldsymbol{n}","\\bfo":"\\boldsymbol{o}","\\bfp":"\\boldsymbol{p}","\\bfq":"\\boldsymbol{q}","\\bfr":"\\boldsymbol{r}","\\bfs":"\\boldsymbol{s}","\\bft":"\\boldsymbol{t}","\\bfu":"\\boldsymbol{u}","\\bfv":"\\boldsymbol{v}","\\bfw":"\\boldsymbol{w}","\\bfx":"\\boldsymbol{x}","\\bfy":"\\boldsymbol{y}","\\bfz":"\\boldsymbol{z}","\\bfA":"\\boldsymbol{A}","\\bfB":"\\boldsymbol{B}","\\bfC":"\\boldsymbol{C}","\\bfD":"\\boldsymbol{D}","\\bfE":"\\boldsymbol{E}","\\bfF":"\\boldsymbol{F}","\\bfG":"\\boldsymbol{G}","\\bfH":"\\boldsymbol{H}","\\bfI":"\\boldsymbol{I}","\\bfJ":"\\boldsymbol{J}","\\bfK":"\\boldsymbol{K}","\\bfL":"\\boldsymbol{L}","\\bfM":"\\boldsymbol{M}","\\bfN":"\\boldsymbol{N}","\\bfO":"\\boldsymbol{O}","\\bfP":"\\boldsymbol{P}","\\bfQ":"\\boldsymbol{Q}","\\bfR":"\\boldsymbol{R}","\\bfS":"\\boldsymbol{S}","\\bfT":"\\boldsymbol{T}","\\bfU":"\\boldsymbol{U}","\\bfV":"\\boldsymbol{V}","\\bfW":"\\boldsymbol{W}","\\bfX":"\\boldsymbol{X}","\\bfY":"\\boldsymbol{Y}","\\bfZ":"\\boldsymbol{Z}"}});$ is the antiferromagnetic Néel vector along with coupling constant $var element = document.getElementById("moose-equation-1d71eda5-01dd-4335-9ea0-4ed9c0af1207");katex.render("A_e", element, {displayMode:false,throwOnError:false,macros:{"\\bs":"\\boldsymbol{#1}","\\normal":"\\bs{n}","\\grad":"\\bs{\\nabla}","\\divergence":"\\grad \\cdot","\\norm":"\\left\\lVert#1\\right\\rVert","\\abs":"\\left\\lvert#1\\right\\rvert","\\tr":"\\text{tr}","\\dev":"\\text{dev}","\\sym":"\\text{sym}","\\diff":"\\text{ d}#1","\\activepart":"{\\left< A \\right>}","\\inactivepart":"{\\left< I \\right>}","\\Gc":"{\\mathcal{G}_c}","\\strain":"\\bs{\\varepsilon}","\\stress":"\\bs{\\sigma}","\\macaulay":"\\left<#1\\right>","\\body":"\\Omega","\\bodyboundary":"{\\partial\\body}","\\ep":"{\\varepsilon^p}","\\ep0":"{\\varepsilon_0^p}","\\epdot":"{\\dot{\\varepsilon}}^p","\\epdot0":"{\\dot{\\varepsilon}}_0^p","\\bfa":"\\boldsymbol{a}","\\bfb":"\\boldsymbol{b}","\\bfc":"\\boldsymbol{c}","\\bfd":"\\boldsymbol{d}","\\bfe":"\\boldsymbol{e}","\\bff":"\\boldsymbol{f}","\\bfg":"\\boldsymbol{g}","\\bfh":"\\boldsymbol{h}","\\bfi":"\\boldsymbol{i}","\\bfj":"\\boldsymbol{j}","\\bfk":"\\boldsymbol{k}","\\bfl":"\\boldsymbol{l}","\\bfm":"\\boldsymbol{m}","\\bfn":"\\boldsymbol{n}","\\bfo":"\\boldsymbol{o}","\\bfp":"\\boldsymbol{p}","\\bfq":"\\boldsymbol{q}","\\bfr":"\\boldsymbol{r}","\\bfs":"\\boldsymbol{s}","\\bft":"\\boldsymbol{t}","\\bfu":"\\boldsymbol{u}","\\bfv":"\\boldsymbol{v}","\\bfw":"\\boldsymbol{w}","\\bfx":"\\boldsymbol{x}","\\bfy":"\\boldsymbol{y}","\\bfz":"\\boldsymbol{z}","\\bfA":"\\boldsymbol{A}","\\bfB":"\\boldsymbol{B}","\\bfC":"\\boldsymbol{C}","\\bfD":"\\boldsymbol{D}","\\bfE":"\\boldsymbol{E}","\\bfF":"\\boldsymbol{F}","\\bfG":"\\boldsymbol{G}","\\bfH":"\\boldsymbol{H}","\\bfI":"\\boldsymbol{I}","\\bfJ":"\\boldsymbol{J}","\\bfK":"\\boldsymbol{K}","\\bfL":"\\boldsymbol{L}","\\bfM":"\\boldsymbol{M}","\\bfN":"\\boldsymbol{N}","\\bfO":"\\boldsymbol{O}","\\bfP":"\\boldsymbol{P}","\\bfQ":"\\boldsymbol{Q}","\\bfR":"\\boldsymbol{R}","\\bfS":"\\boldsymbol{S}","\\bfT":"\\boldsymbol{T}","\\bfU":"\\boldsymbol{U}","\\bfV":"\\boldsymbol{V}","\\bfW":"\\boldsymbol{W}","\\bfX":"\\boldsymbol{X}","\\bfY":"\\boldsymbol{Y}","\\bfZ":"\\boldsymbol{Z}"}});$ .

Example Input File Syntax

Input Parameters

Neel_L_xThe x component of the AFM Neel vector
C++ Type:std::vector<VariableName>
Controllable:No
Description:The x component of the AFM Neel vector
Neel_L_yThe y component of the AFM Neel vector
C++ Type:std::vector<VariableName>
Controllable:No
Description:The y component of the AFM Neel vector
Neel_L_zThe z component of the AFM Neel vector
C++ Type:std::vector<VariableName>
Controllable:No
Description:The z component of the AFM Neel vector

Required Parameters

blockThe list of blocks (ids or names) that this object will be applied
C++ Type:std::vector<SubdomainName>
Controllable:No
Description:The list of blocks (ids or names) that this object will be applied
energy_scale1the energy scale, useful for transition between eV to/from aJ
Default:1
C++ Type:double
Controllable:No
Description:the energy scale, useful for transition between eV to/from aJ
execute_onTIMESTEP_ENDThe list of flag(s) indicating when this object should be executed, the available options include NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, ALWAYS.
Default:TIMESTEP_END
C++ Type:ExecFlagEnum
Options:NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, ALWAYS, TRANSFER
Controllable:No
Description:The list of flag(s) indicating when this object should be executed, the available options include NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, ALWAYS.
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.

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
implicitTrueDetermines whether this object is calculated using an implicit or explicit form
Default:True
C++ Type:bool
Controllable:No
Description:Determines whether this object is calculated using an implicit or explicit form
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
seed0The seed for the master random number generator
Default:0
C++ Type:unsigned int
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
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

(tutorial/BFO_mag_wall_rd.i)

(tutorial/BFO_mag_wall_rd.i)



  ##############################
  ##
  ## UNITS:
  ##
  ##   gamma = (2.2101*10^5 / 2 pi) m/C
  ##
  ##   gamma/(mu*0Ms) = 48291.9 nm*mus/pg
  ##
  ##   coefficients given in (pg/nm*mus) 
  ##   which is equivalent to an energy/vol
  ##
  ##   Effective fields are 1/(mu0*Ms)*coeff
  ##   which gives units of aC/(nm*mus)
  ##
  ##   Energies are natively printed in units 
  ##    of 0.160218 pg nm^2 / mus^2 
  ##    or 1.60218*10^{-22} J
  ##    or 0.001 eV
  ##
  ##############################


Dedef = 3.7551

D0def = 0.003

K1def = -5.0068

K1cdef = -0.0550748

Ktdef = -0.00365997

alphadef = 0.8

#freq = 0.2

corr = 0.0005
dwid = 0.5

hamp = 0.35355339059327373
fDW = 7.88
sDW = 23.53

[Mesh]
  [fileload]
    type = FileMeshGenerator
    file = BFO_dwP1A1_100_ref.e
    use_for_exodus_restart = true
  []
[]


[GlobalParams]
  mag1_x = mag1_x
  mag1_y = mag1_y
  mag1_z = mag1_z

  mag2_x = mag2_x
  mag2_y = mag2_y
  mag2_z = mag2_z

  antiphase_A_x = antiphase_A_x
  antiphase_A_y = antiphase_A_y
  antiphase_A_z = antiphase_A_z

  polar_x = polar_x
  polar_y = polar_y
  polar_z = polar_z


[]

[Materials]
  ############################################################################
  ##==
  ##       material constants used.
  ##
  ##
  ############################################################################

  [./constants] 
    type = GenericConstantMaterial
    prop_names = ' alpha           De       D0             g0mu0Ms      g0          K1         K1c      Kt     permittivity Ae     Ms '
    prop_values = '${alphadef}   ${Dedef} ${D0def}      48291.9      48291.9     ${K1def}  ${K1cdef} ${Ktdef}     1.0      0.75    1.0 '
  [../]

  [./a_long]
    type = GenericFunctionMaterial
    prop_names = 'alpha_long'
    prop_values = 'bc_func_1'
  [../]

[]

[Functions]

  ##############################
  ##
  ## Define the ramping function
  ## expression to be used
  ##==
  ##############################

  [./bc_func_1]
    type = ParsedFunction
    value = 'st'
    vars = 'st'
    vals = '1e8'
  [../]


  [./stripem1x]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,(${hamp}+${corr})*tanh(${dwid}*(x-${fDW}))+${hamp},-(${hamp}+${corr})*tanh(${dwid}*(x-${sDW}))+${hamp})'
  [../]

  [./stripem1y]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,-(2*${hamp}+${corr})*tanh(${dwid}*(x-${fDW})),(2*${hamp}+${corr})*tanh(${dwid}*(x-${sDW})))'
  [../]
  [./stripem1z]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,-(${hamp}+${corr})*tanh(${dwid}*(x-${fDW}))+${hamp},(${hamp}+${corr})*tanh(${dwid}*(x-${sDW}))+${hamp})'
  [../]

  [./stripem2x]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,-(${hamp}-${corr})*tanh(${dwid}*(x-${fDW}))-${hamp},(${hamp}-${corr})*tanh(${dwid}*(x-${sDW}))-${hamp})'
  [../]
  [./stripem2y]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,(2*${hamp}-${corr})*tanh(${dwid}*(x-${fDW})),-(2*${hamp}-${corr})*tanh(${dwid}*(x-${sDW})))'
  [../]
  [./stripem2z]
    type = ParsedFunction
    value = 'if(x < 15.707963267948966,(${hamp}-${corr})*tanh(${dwid}*(x-${fDW}))-${hamp},-(${hamp}-${corr})*tanh(${dwid}*(x-${sDW}))-${hamp})'
  [../]
[]
#==

[Variables]
  [./mag1_x]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem1x
    [../]
  [../]
  [./mag1_y]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem1y
    [../]
  [../]
  [./mag1_z]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem1z
    [../]
  [../]

  [./mag2_x]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem2x
    [../]
  [../]
  [./mag2_y]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem2y
    [../]
  [../]
  [./mag2_z]
    order = FIRST
    family = LAGRANGE
    [./InitialCondition]
      type = FunctionIC
      function = stripem2z
    [../]
  [../]
[]

[AuxVariables]

  [./mag1_s]
    order = FIRST
    family = LAGRANGE
  [../]
  [./mag2_s]
    order = FIRST
    family = LAGRANGE
  [../]

  [./Neel_L_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./Neel_L_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./Neel_L_z]
    order = FIRST
    family = LAGRANGE
  [../]


  [./SSMag_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./SSMag_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./SSMag_z]
    order = FIRST
    family = LAGRANGE
  [../]


  [./antiphase_A_x]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = antiphase_A_x
    initial_from_file_timestep = 'LATEST'
  [../]
  [./antiphase_A_y]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = antiphase_A_y
    initial_from_file_timestep = 'LATEST'
  [../]
  [./antiphase_A_z]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = antiphase_A_z
    initial_from_file_timestep = 'LATEST'
  [../]


  [./polar_x]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = polar_x
    initial_from_file_timestep = 'LATEST'
  [../]
  [./polar_y]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = polar_y
    initial_from_file_timestep = 'LATEST'
  [../]
  [./polar_z]
    order = FIRST
    family = LAGRANGE
    initial_from_file_var = polar_z
    initial_from_file_timestep = 'LATEST'
  [../]

  [./dSSMag_dt_x]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dSSMag_dt_y]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dSSMag_dt_z]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./dL_dt_x]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dL_dt_y]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dL_dt_z]
    order = CONSTANT
    family = MONOMIAL
  [../]

  #############################################################
  ##
  ##  other angles
  ##
  ###########################################################

  [./ph]
    order = FIRST
    family = LAGRANGE
  [../]

  [./th1]
    order = FIRST
    family = LAGRANGE
  [../]
  [./th2]
    order = FIRST
    family = LAGRANGE
  [../]

  ######################
  ##                  ##
  ##  Energy density  ##
  ##                  ##
  ######################

  [./Edmi]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Esupexch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Enlexch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Eepa1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Eepa2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Eca1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Eca2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Etot]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]
  #---------------------------------------#
  #                                       #
  #          Time dependence              #
  #                                       #
  #---------------------------------------#

  [./mag1_x_time]
    type = TimeDerivative
    variable = mag1_x
  [../]
  [./mag1_y_time]
    type = TimeDerivative
    variable = mag1_y
  [../]
  [./mag1_z_time]
    type = TimeDerivative
    variable = mag1_z
  [../]

  [./mag2_x_time]
    type = TimeDerivative
    variable = mag2_x
  [../]
  [./mag2_y_time]
    type = TimeDerivative
    variable = mag2_y
  [../]
  [./mag2_z_time]
    type = TimeDerivative
    variable = mag2_z
  [../]


  #---------------------------------------#
  #                                       #
  #     AFM sublattice exchange           #
  #                                       #
  #---------------------------------------#

  [./afmex1_x]
    type = AFMSublatticeSuperexchange
    variable = mag1_x
    mag_sub = 0
    component = 0
  [../]
  [./afmex1_y]
    type = AFMSublatticeSuperexchange
    variable = mag1_y
    mag_sub = 0
    component = 1
  [../]
  [./afmex1_z]
    type = AFMSublatticeSuperexchange
    variable = mag1_z
    mag_sub = 0
    component = 2
  [../]

  [./afmex2_x]
    type = AFMSublatticeSuperexchange
    variable = mag2_x
    mag_sub = 1
    component = 0
  [../]
  [./afmex2_y]
    type = AFMSublatticeSuperexchange
    variable = mag2_y
    mag_sub = 1
    component = 1
  [../]
  [./afmex2_z]
    type = AFMSublatticeSuperexchange
    variable = mag2_z
    mag_sub = 1
    component = 2
  [../]

  #---------------------------------------#
  #                                       #
  #     AFM sublattice DMI                #
  #                                       #
  #---------------------------------------#

  [./afmdmi1_x]
    type = AFMSublatticeDMInteraction
    variable = mag1_x
    mag_sub = 0
    component = 0
  [../]
  [./afmdmi1_y]
    type = AFMSublatticeDMInteraction
    variable = mag1_y
    mag_sub = 0
    component = 1
  [../]
  [./afmdmi1_z]
    type = AFMSublatticeDMInteraction
    variable = mag1_z
    mag_sub = 0
    component = 2
  [../]

  [./afmdmi2_x]
    type = AFMSublatticeDMInteraction
    variable = mag2_x
    mag_sub = 1
    component = 0
  [../]
  [./afmdmi2_y]
    type = AFMSublatticeDMInteraction
    variable = mag2_y
    mag_sub = 1
    component = 1
  [../]
  [./afmdmi2_z]
    type = AFMSublatticeDMInteraction
    variable = mag2_z
    mag_sub = 1
    component = 2
  [../]

  #---------------------------------------#
  #                                       #
  #   Magnetocrystalline anisotropy for   #
  #   the AFM sublattice in easy-plane    #
  #                                       #
  #---------------------------------------#

  [./afma1_x]
    type = AFMEasyPlaneAnisotropy
    variable = mag1_x
    mag_sub = 0
    component = 0
  [../]
  [./afma1_y]
    type = AFMEasyPlaneAnisotropy
    variable = mag1_y
    mag_sub = 0
    component = 1
  [../]
  [./afma1_z]
    type = AFMEasyPlaneAnisotropy
    variable = mag1_z
    mag_sub = 0
    component = 2
  [../]


  [./afma2_x]
    type = AFMEasyPlaneAnisotropy
    variable = mag2_x
    mag_sub = 1
    component = 0
  [../]
  [./afma2_y]
    type = AFMEasyPlaneAnisotropy
    variable = mag2_y
    mag_sub = 1
    component = 1
  [../]
  [./afma2_z]
    type = AFMEasyPlaneAnisotropy
    variable = mag2_z
    mag_sub = 1
    component = 2
  [../]


  #---------------------------------------#
  #                                       #
  #   Single-ion anisotropy environment   #
  #   for the AFM sublattice in the       #
  #   degenerate easy-plane               #
  #                                       #
  #---------------------------------------#

  [./afmsia1_x]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag1_x
    mag_sub = 0
    component = 0
  [../]
  [./afmsia1_y]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag1_y
    mag_sub = 0
    component = 1
  [../]
  [./afmsia1_z]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag1_z
    mag_sub = 0
    component = 2
  [../]

  [./afmsia2_x]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag2_x
    mag_sub = 1
    component = 0
  [../]
  [./afmsia2_y]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag2_y
    mag_sub = 1
    component = 1
  [../]
  [./afmsia2_z]
    type = AFMSingleIonCubicSixthAnisotropy
    variable = mag2_z
    mag_sub = 1
    component = 2
  [../]

  #---------------------------------------#
  #                                       #
  #          LLB constraint terms         #
  #                                       #
  #---------------------------------------#

  [./llb1_x]
    type = LongitudinalLLB
    variable = mag1_x
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    component = 0
  [../]
  [./llb1_y]
    type = LongitudinalLLB
    variable = mag1_y
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    component = 1
  [../]

  [./llb1_z]
    type = LongitudinalLLB
    variable = mag1_z
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    component = 2
  [../]

  [./llb2_x]
    type = LongitudinalLLB
    variable = mag2_x
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    component = 0
  [../]
  [./llb2_y]
    type = LongitudinalLLB
    variable = mag2_y
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    component = 1
  [../]

  [./llb2_z]
    type = LongitudinalLLB
    variable = mag2_z
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    component = 2
  [../]

  #---------------------------------------#
  #                                       #
  #    Local magnetic exchange            #
  #                                       #
  #---------------------------------------#
  
  [./dllg1_x_exch]
    type = ExchangeCartLL
    variable = mag1_x
    component = 0
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
  [../]
  [./dllg1_y_exch]
    type = ExchangeCartLL
    variable = mag1_y
    component = 1
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
  [../]
  [./dllg1_z_exch]
    type = ExchangeCartLL
    variable = mag1_z
    component = 2
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
  [../]

  [./dllg2_x_exch]
    type = ExchangeCartLL
    variable = mag2_x
    component = 0
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
  [../]
  [./dllg2_y_exch]
    type = ExchangeCartLL
    variable = mag2_y
    component = 1
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
  [../]
  [./dllg2_z_exch]
    type = ExchangeCartLL
    variable = mag2_z
    component = 2
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
  [../]

  #---------------------------------------#
  #                                       #=
  #    Local AFM magnetic exchange        #
  #           (Local-term)                #
  #---------------------------------------#
  
  [./dllg1afm_x_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag1_x
    mag_sub = 0
    component = 0
  [../]
  [./dllg1afm_y_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag1_y
    mag_sub = 0
    component = 1
  [../]
  [./dllg1afm_z_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag1_z
    mag_sub = 0
    component = 2
  [../]

  [./dllg2afm_x_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag2_x
    mag_sub = 1
    component = 0
  [../]
  [./dllg2afm_y_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag2_y
    mag_sub = 1
    component = 1
  [../]
  [./dllg2afm_z_exch]
    type = AFMLocalSublatticeExchangeCartLL
    variable = mag2_z
    mag_sub = 1
    component = 2
  [../]
[]



[AuxKernels]
  [./mag1_mag]
    type = VectorMag
    variable = mag1_s
    vector_x = mag1_x
    vector_y = mag1_y
    vector_z = mag1_z
    execute_on = 'initial timestep_end final'
  [../]

  [./mag2_mag]
    type = VectorMag
    variable = mag2_s
    vector_x = mag2_x
    vector_y = mag2_y
    vector_z = mag2_z
    execute_on = 'initial timestep_end final'
  [../]


  [./Neel_Lx]
    type = VectorDiffOrSum
    variable = Neel_L_x
    var1 = mag1_x
    var2 = mag2_x
    diffOrSum = 0
    execute_on = 'initial timestep_end final'
  [../]
  [./Neel_Ly]
    type = VectorDiffOrSum
    variable = Neel_L_y
    var1 = mag1_y
    var2 = mag2_y
    diffOrSum = 0
    execute_on = 'initial timestep_end final'
  [../]
  [./Neel_Lz]
    type = VectorDiffOrSum
    variable = Neel_L_z
    var1 = mag1_z
    var2 = mag2_z
    diffOrSum = 0
    execute_on = 'initial timestep_end final'
  [../]

  [./smallSignalMag_x]
    type = VectorDiffOrSum
    variable = SSMag_x
    var1 = mag1_x
    var2 = mag2_x
    diffOrSum = 1
    execute_on = 'initial timestep_end final'
  [../]
  [./smallSignalMag_y]
    type = VectorDiffOrSum
    variable = SSMag_y
    var1 = mag1_y
    var2 = mag2_y
    diffOrSum = 1
    execute_on = 'initial timestep_end final'
  [../]
  [./smallSignalMag_z]
    type = VectorDiffOrSum
    variable = SSMag_z
    var1 = mag1_z
    var2 = mag2_z
    diffOrSum = 1
    execute_on = 'initial timestep_end final'
  [../]

  [./phc]
    type = AngleBetweenTwoVectors
    variable = ph
    var1x = mag1_x
    var1y = mag1_y
    var1z = mag1_z
    var2x = mag2_x
    var2y = mag2_y
    var2z = mag2_z

    execute_on = 'initial timestep_end final'
  [../]

  [./th1c]
    type = AngleBetweenTwoVectors
    variable = th1
    var1x = mag1_x
    var1y = mag1_y
    var1z = mag1_z
    var2x = polar_x
    var2y = polar_y
    var2z = polar_z

    execute_on = 'initial timestep_end final'
  [../]

  [./th2c]
    type = AngleBetweenTwoVectors
    variable = th2
    var1x = mag2_x
    var1y = mag2_y
    var1z = mag2_z
    var2x = polar_x
    var2y = polar_y
    var2z = polar_z

    execute_on = 'initial timestep_end final'
  [../]

  #---------------------------------------#
  #                                       #
  #          Energy density               #
  #                                       #
  #---------------------------------------#

  [./cEdmi]
    type = AFMSublatticeDMInteractionEnergyDensity
    variable = Edmi
    execute_on = 'initial timestep_end final'
    energy_scale = -6241.51
  [../]
  [./cEsupexch]
    type = AFMSublatticeSuperexchangeEnergyDensity
    variable = Esupexch
    execute_on = 'initial timestep_end final'
    energy_scale = 6241.51
  [../]
  [./cEnlexch]
    type = AFMExchangeStiffnessEnergyDensity
    variable = Enlexch
    Neel_L_x = Neel_L_x
    Neel_L_y = Neel_L_y
    Neel_L_z = Neel_L_z
    execute_on = 'initial timestep_end final'
    energy_scale = 6241.51
  [../]

  [./cEepa1]
    type = AFMEasyPlaneAnisotropyEnergyDensity
    variable = Eepa1
    execute_on = 'initial timestep_end final'
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    energy_scale = 6241.51
  [../]
  [./cEepa2]
    type = AFMEasyPlaneAnisotropyEnergyDensity
    variable = Eepa2
    execute_on = 'initial timestep_end final'
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    energy_scale = 6241.51
  [../]
  [./cEca1]
    type = AFMSingleIonCubicSixthAnisotropyEnergyDensity
    variable = Eca1
    execute_on = 'initial timestep_end final'
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    energy_scale = 6241.51
  [../]
  [./cEca2]
    type = AFMSingleIonCubicSixthAnisotropyEnergyDensity
    variable = Eca2
    execute_on = 'initial timestep_end final'
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    energy_scale = 6241.51
  [../]

  [./cEdtot]
    type = AFMTotalEnergyDensity
    variable = Etot
    execute_on = 'initial timestep_end final'
    Edmi = Edmi
    Esupexch = Esupexch
    Enlexch = Enlexch
    Eepa1 = Eepa1
    Eepa2 = Eepa2
    Eca1 = Eca1
    Eca2 = Eca2
  [../]

[]


[BCs]
  #---------------------------------------#
  #                                       #
  #  periodic magnetization distribution  #
  #                                       #
  #---------------------------------------#

  [./Periodic]
    [./x]
      auto_direction = 'x'
      variable = 'mag1_x mag1_y mag1_z mag2_x mag2_y mag2_z'
    [../]
  [../]

[]

[Postprocessors]
   [./dt]
     type = TimestepSize
   [../]

  #---------------------------------------#
  #                                       #
  #     Average Mk = |m_k| and along      # 
  #     other directions                  #
  #                                       #
  #---------------------------------------#

  [./M1]
    type = ElementAverageValue
    variable = mag1_s
    execute_on = 'initial timestep_end final'
  [../]
  [./M2]
    type = ElementAverageValue
    variable = mag2_s
    execute_on = 'initial timestep_end final'
  [../]

  [./<Lx>]
    type = ElementAverageValue
    variable = Neel_L_x
    execute_on = 'initial timestep_end final'
  [../]
  [./<Ly>]
    type = ElementAverageValue
    variable = Neel_L_y
    execute_on = 'initial timestep_end final'
  [../]
  [./<Lz>]
    type = ElementAverageValue
    variable = Neel_L_z
    execute_on = 'initial timestep_end final'
  [../]

  [./<m1x>]
    type = ElementAverageValue
    variable = mag1_x
    execute_on = 'initial timestep_end final'
  [../]
  [./<m1y>]
    type = ElementAverageValue
    variable = mag1_y
    execute_on = 'initial timestep_end final'
  [../]
  [./<m1z>]
    type = ElementAverageValue
    variable = mag1_z
    execute_on = 'initial timestep_end final'
  [../]

  [./<m2x>]
    type = ElementAverageValue
    variable = mag2_x
    execute_on = 'initial timestep_end final'
  [../]
  [./<m2y>]
    type = ElementAverageValue
    variable = mag2_y
    execute_on = 'initial timestep_end final'
  [../]
  [./<m2z>]
    type = ElementAverageValue
    variable = mag2_z
    execute_on = 'initial timestep_end final'
  [../]

  [./<ph>]
    type = ElementAverageValue
    variable = ph
    execute_on = 'initial timestep_end final'
  [../]
  [./<th1>]
    type = ElementAverageValue
    variable = th1
    execute_on = 'initial timestep_end final'
  [../]
  [./<th2>]
    type = ElementAverageValue
    variable = th2
    execute_on = 'initial timestep_end final'
  [../]

  #---------------------------------------#
  #                                       #
  #   Calculate exchange energy of        #
  #   the magnetic body                   #
  #                                       #
  #---------------------------------------#

  [./FafmSLexch]
    type = AFMSublatticeSuperexchangeEnergy
    execute_on = 'initial timestep_end final'
    mag1_x = mag1_x
    mag1_y = mag1_y
    mag1_z = mag1_z
    mag2_x = mag2_x
    mag2_y = mag2_y
    mag2_z = mag2_z
    energy_scale = 0.001

  [../]
  [./FafmSLdmi]
    type = AFMSublatticeDMInteractionEnergy
    execute_on = 'initial timestep_end final'
    energy_scale = 0.001
  [../]

  [./FexchS]
    type = AFMExchangeStiffnessEnergy
    execute_on = 'initial timestep_end final'
    energy_scale = 0.001
    Neel_L_x = Neel_L_x
    Neel_L_y = Neel_L_y
    Neel_L_z = Neel_L_z
  [../]

  #---------------------------------------#
  #                                       #
  #   Calculate excess energy from missed #
  #   LLB targets                         #
  #                                       #
  #---------------------------------------#

  [./Fllb1]
    type = MagneticExcessLLBEnergy
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    execute_on = 'initial timestep_end final'
  [../]
  [./Fllb2]
    type = MagneticExcessLLBEnergy
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    execute_on = 'initial timestep_end final'
  [../]

  #---------------------------------------#
  #                                       #
  #   Calculate the anisotropy energy     #
  #                                       #
  #---------------------------------------#

  [./Fa1]
    type = AFMEasyPlaneAnisotropyEnergy
    execute_on = 'initial timestep_end final'
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    energy_scale = 0.001
  [../]
  [./Fa2]
    type = AFMEasyPlaneAnisotropyEnergy
    execute_on = 'initial timestep_end final'
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    energy_scale = 0.001
  [../]

  [./Fsia1]
    type = AFMSingleIonCubicSixthAnisotropyEnergy
    execute_on = 'initial timestep_end final'
    mag_x = mag1_x
    mag_y = mag1_y
    mag_z = mag1_z
    energy_scale = 0.001
  [../]
  [./Fsia2]
    type = AFMSingleIonCubicSixthAnisotropyEnergy
    execute_on = 'initial timestep_end final'
    mag_x = mag2_x
    mag_y = mag2_y
    mag_z = mag2_z
    energy_scale = 0.001
  [../]

  #---------------------------------------#
  #                                       #
  #   add all the energy contributions    #
  #   and calculate their percent change  #
  #                                       #
  #---------------------------------------#

  [./Ftot]
    type = LinearCombinationPostprocessor 
    pp_names = 'FafmSLexch FafmSLdmi Fa1 Fa2 Fsia1 Fsia2 FexchS'
    pp_coefs = ' 1.0 1.0 1.0 1.0 1.0 1.0 1.0'
    execute_on = 'initial timestep_end final'
  [../]

  [./FtotLLB]
    type = LinearCombinationPostprocessor 
    pp_names = 'Fllb1 Fllb2'
    pp_coefs = ' 1.0 1.0'
    execute_on = 'initial timestep_end final'
  [../]

  [./perc_change]
    type = EnergyRatePostprocessor
    postprocessor = Ftot
    dt = dt 
    execute_on = 'timestep_end final'
  [../]

  [./elapsed]
    type = PerfGraphData
    section_name = "Root"  # for profiling the problem
    data_type = total
  [../]
[]

[UserObjects]
  [./kill]
    type = Terminator
    expression = 'perc_change <= 1.0e-8'
  [../]
[]

[Preconditioning]

  #---------------------------------------#
  #                                       #
  #            Solver options             #
  #                                       #
  #---------------------------------------#

  [./smp]
    type = SMP
    full = true
    petsc_options_iname = ' -ksp_gmres_restart -snes_atol -snes_rtol -ksp_rtol -pc_type '
    petsc_options_value = '    250               1e-8      1e-8      1e-5     bjacobi'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'

  [./TimeIntegrator]
    type = NewmarkBeta
  [../]

  dtmin = 1e-18
  dtmax = 1e-7

  [./TimeStepper]
    type = IterationAdaptiveDT
    optimal_iterations = 25  #usually 10
    linear_iteration_ratio = 100
    dt = 1e-9
    growth_factor = 1.1
  [../]

  num_steps = 18001
[]

[Outputs]
  print_linear_residuals = false
  [./out]
    type = Exodus
    file_base = out_BFO_P111bA111b-P111bA111b_m1
    elemental_as_nodal = true
    interval = 20
  [../]
  [./outCSV]
    type = CSV
    file_base = out_BFO_P111bA111b-P111bA111b_m1
  [../]
[]