Merge branch 'nonlocal-compatibility-in-dependent-state' into 'development'
Nonlocal compatibility in dependent state See merge request damask/DAMASK!891
This commit is contained in:
commit
112b5be1ad
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@ -326,11 +326,6 @@ module phase
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real(pREAL) :: f
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end function phase_f_T
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module subroutine plastic_nonlocal_updateCompatibility(orientation,ce)
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integer, intent(in) :: ce
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type(tRotationContainer), dimension(:), intent(in) :: orientation
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end subroutine plastic_nonlocal_updateCompatibility
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module subroutine plastic_dependentState(ph,en)
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integer, intent(in) :: &
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ph, &
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@ -363,7 +358,6 @@ module phase
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phase_allocateState, &
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phase_forward, &
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phase_restore, &
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plastic_nonlocal_updateCompatibility, &
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converged, &
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phase_mechanical_constitutive, &
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phase_thermal_constitutive, &
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@ -576,9 +570,6 @@ subroutine crystallite_orientations(co,ce)
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call phase_O(ph)%data(en)%fromMatrix(transpose(math_rotationalPart(mechanical_F_e(ph,en))))
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if (plasticState(material_ID_phase(1,ce))%nonlocal) call plastic_nonlocal_updateCompatibility(phase_O,ce)
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end subroutine crystallite_orientations
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@ -204,6 +204,11 @@ submodule(phase:mechanical) plastic
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en
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end subroutine plastic_nonlocal_deltaState
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module subroutine plastic_nonlocal_updateCompatibility(orientation,ph,en)
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integer, intent(in) :: ph, en
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type(tRotationContainer), dimension(:), intent(in) :: orientation
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end subroutine plastic_nonlocal_updateCompatibility
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end interface
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contains
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@ -359,6 +364,7 @@ module subroutine plastic_dependentState(ph,en)
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case (MECHANICAL_PLASTICITY_NONLOCAL) plasticType
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call nonlocal_dependentState(ph,en)
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if (plasticState(ph)%nonlocal) call plastic_nonlocal_updateCompatibility(phase_O,ph,en)
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end select plasticType
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@ -6,18 +6,18 @@
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!--------------------------------------------------------------------------------------------------
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submodule(phase:plastic) nonlocal
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use geometry_plastic_nonlocal, only: &
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nIPneighbors => geometry_plastic_nonlocal_nIPneighbors, &
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nCellNeighbors => geometry_plastic_nonlocal_nIPneighbors, &
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IPneighborhood => geometry_plastic_nonlocal_IPneighborhood, &
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IPvolume => geometry_plastic_nonlocal_IPvolume0, &
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IParea => geometry_plastic_nonlocal_IParea0, &
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IPareaNormal => geometry_plastic_nonlocal_IPareaNormal0, &
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IPvolume0 => geometry_plastic_nonlocal_IPvolume0, &
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IParea0 => geometry_plastic_nonlocal_IParea0, &
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IPareaNormal0 => geometry_plastic_nonlocal_IPareaNormal0, &
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geometry_plastic_nonlocal_disable
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type :: tGeometry
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real(pREAL), dimension(:), allocatable :: V_0
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real(pREAL), dimension(:), allocatable :: v_0
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real(pREAL), dimension(:,:), allocatable :: a_0, x_0
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real(pREAL), dimension(:,:,:), allocatable :: n_0
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integer, dimension(:,:,:), allocatable :: IPneighborhood
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real(pREAL), dimension(:,:), allocatable :: IParea, IPcoordinates
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real(pREAL), dimension(:,:,:), allocatable :: IPareaNormal
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end type tGeometry
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type(tGeometry), dimension(:), allocatable :: geom
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@ -41,12 +41,6 @@ submodule(phase:plastic) nonlocal
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mob_scr_pos = 3, & !< mobile screw positive
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mob_scr_neg = 4 !< mobile screw positive
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! BEGIN DEPRECATED
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integer, dimension(:,:,:), allocatable :: &
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iRhoU, & !< state indices for unblocked density
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iV !< state indices for dislocation velocities
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!END DEPRECATED
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real(pREAL), dimension(:,:,:,:,:,:), allocatable :: &
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compatibility !< slip system compatibility between en and my neighbors
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@ -133,18 +127,18 @@ submodule(phase:plastic) nonlocal
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type :: tNonlocalState
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real(pREAL), pointer, dimension(:,:) :: &
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rho, & ! < all dislocations
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rhoSgl, &
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rhoSglMobile, & ! iRhoU
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rho_sgl, &
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rho_sgl_mob, &
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rho_sgl_mob_edg_pos, &
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rho_sgl_mob_edg_neg, &
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rho_sgl_mob_scr_pos, &
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rho_sgl_mob_scr_neg, &
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rhoSglImmobile, &
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rho_sgl_imm, &
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rho_sgl_imm_edg_pos, &
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rho_sgl_imm_edg_neg, &
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rho_sgl_imm_scr_pos, &
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rho_sgl_imm_scr_neg, &
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rhoDip, &
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rho_dip, &
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rho_dip_edg, &
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rho_dip_scr, &
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gamma, &
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@ -178,8 +172,7 @@ module function plastic_nonlocal_init() result(myPlasticity)
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ph, &
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Nmembers, &
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sizeState, sizeDotState, sizeDeltaState, &
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s1, s2, &
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s, t, l
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s1, s2
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real(pREAL), dimension(:,:), allocatable :: &
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a_nS !< non-Schmid coefficients
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character(len=:), allocatable :: &
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@ -383,12 +376,12 @@ module function plastic_nonlocal_init() result(myPlasticity)
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!--------------------------------------------------------------------------------------------------
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! allocate state arrays
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Nmembers = count(material_ID_phase == ph)
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sizeDotState = size([ 'rhoSglEdgePosMobile ','rhoSglEdgeNegMobile ', &
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'rhoSglScrewPosMobile ','rhoSglScrewNegMobile ', &
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'rhoSglEdgePosImmobile ','rhoSglEdgeNegImmobile ', &
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'rhoSglScrewPosImmobile','rhoSglScrewNegImmobile', &
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'rhoDipEdge ','rhoDipScrew ', &
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'gamma ' ]) * prm%sum_N_sl !< "basic" microstructural state variables that are independent from other state variables
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sizeDotState = size(['rho_sgl_mob_edg_pos', 'rho_sgl_mob_edg_neg', &
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'rho_sgl_mob_scr_pos', 'rho_sgl_mob_scr_neg', &
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'rho_sgl_imm_edg_pos', 'rho_sgl_imm_edg_neg', &
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'rho_sgl_imm_scr_pos', 'rho_sgl_imm_scr_neg', &
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'rho_dip_edg ', 'rho_dip_scr ', &
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'gamma ' ]) * prm%sum_N_sl !< "basic" microstructural state variables that are independent from other state variables
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sizeState = sizeDotState &
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+ size([ 'velocityEdgePos ','velocityEdgeNeg ', &
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'velocityScrewPos ','velocityScrewNeg ']) * prm%sum_N_sl !< other dependent state variables that are not updated by microstructure
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@ -396,11 +389,11 @@ module function plastic_nonlocal_init() result(myPlasticity)
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call phase_allocateState(plasticState(ph),Nmembers,sizeState,sizeDotState,sizeDeltaState,0) ! ToDo: state structure does not follow convention
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allocate(geom(ph)%V_0(Nmembers))
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allocate(geom(ph)%IPneighborhood(3,nIPneighbors,Nmembers))
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allocate(geom(ph)%IPareaNormal(3,nIPneighbors,Nmembers))
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allocate(geom(ph)%IParea(nIPneighbors,Nmembers))
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allocate(geom(ph)%IPcoordinates(3,Nmembers))
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allocate(geom(ph)%v_0(Nmembers))
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allocate(geom(ph)%a_0(nCellNeighbors,Nmembers))
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allocate(geom(ph)%x_0(3,Nmembers))
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allocate(geom(ph)%n_0(3,nCellNeighbors,Nmembers))
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allocate(geom(ph)%IPneighborhood(3,nCellNeighbors,Nmembers))
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call storeGeometry(ph)
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if (plasticState(ph)%nonlocal .and. .not. allocated(IPneighborhood)) &
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@ -412,13 +405,14 @@ module function plastic_nonlocal_init() result(myPlasticity)
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del%rho => plasticState(ph)%deltaState (0*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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plasticState(ph)%atol(1:10*prm%sum_N_sl) = prm%atol_rho
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stt%rhoSgl => plasticState(ph)%state (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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dot%rhoSgl => plasticState(ph)%dotState (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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del%rhoSgl => plasticState(ph)%deltaState (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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stt%rho_sgl => plasticState(ph)%state (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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dot%rho_sgl => plasticState(ph)%dotState (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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del%rho_sgl => plasticState(ph)%deltaState (0*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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stt%rhoSglMobile => plasticState(ph)%state (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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dot%rhoSglMobile => plasticState(ph)%dotState (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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del%rhoSglMobile => plasticState(ph)%deltaState (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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st0%rho_sgl_mob => plasticState(ph)%state0 (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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stt%rho_sgl_mob => plasticState(ph)%state (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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dot%rho_sgl_mob => plasticState(ph)%dotState (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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del%rho_sgl_mob => plasticState(ph)%deltaState (0*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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stt%rho_sgl_mob_edg_pos => plasticState(ph)%state (0*prm%sum_N_sl+1: 1*prm%sum_N_sl,:)
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dot%rho_sgl_mob_edg_pos => plasticState(ph)%dotState (0*prm%sum_N_sl+1: 1*prm%sum_N_sl,:)
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@ -436,9 +430,9 @@ module function plastic_nonlocal_init() result(myPlasticity)
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dot%rho_sgl_mob_scr_neg => plasticState(ph)%dotState (3*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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del%rho_sgl_mob_scr_neg => plasticState(ph)%deltaState (3*prm%sum_N_sl+1: 4*prm%sum_N_sl,:)
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stt%rhoSglImmobile => plasticState(ph)%state (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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dot%rhoSglImmobile => plasticState(ph)%dotState (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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del%rhoSglImmobile => plasticState(ph)%deltaState (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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stt%rho_sgl_imm => plasticState(ph)%state (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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dot%rho_sgl_imm => plasticState(ph)%dotState (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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del%rho_sgl_imm => plasticState(ph)%deltaState (4*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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stt%rho_sgl_imm_edg_pos => plasticState(ph)%state (4*prm%sum_N_sl+1: 5*prm%sum_N_sl,:)
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dot%rho_sgl_imm_edg_pos => plasticState(ph)%dotState (4*prm%sum_N_sl+1: 5*prm%sum_N_sl,:)
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@ -456,9 +450,9 @@ module function plastic_nonlocal_init() result(myPlasticity)
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dot%rho_sgl_imm_scr_neg => plasticState(ph)%dotState (7*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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del%rho_sgl_imm_scr_neg => plasticState(ph)%deltaState (7*prm%sum_N_sl+1: 8*prm%sum_N_sl,:)
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stt%rhoDip => plasticState(ph)%state (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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dot%rhoDip => plasticState(ph)%dotState (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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del%rhoDip => plasticState(ph)%deltaState (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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stt%rho_dip => plasticState(ph)%state (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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dot%rho_dip => plasticState(ph)%dotState (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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del%rho_dip => plasticState(ph)%deltaState (8*prm%sum_N_sl+1:10*prm%sum_N_sl,:)
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stt%rho_dip_edg => plasticState(ph)%state (8*prm%sum_N_sl+1: 9*prm%sum_N_sl,:)
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dot%rho_dip_edg => plasticState(ph)%dotState (8*prm%sum_N_sl+1: 9*prm%sum_N_sl,:)
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@ -486,7 +480,7 @@ module function plastic_nonlocal_init() result(myPlasticity)
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allocate(dst%tau_back(prm%sum_N_sl,Nmembers),source=0.0_pREAL)
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allocate(dst%rho_forest(prm%sum_N_sl,Nmembers),source=0.0_pREAL)
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allocate(dst%max_dipole_height(2*prm%sum_N_sl,Nmembers),source=0.0_pREAL) ! edge and screw
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allocate(dst%compatibility(2,maxval(param%sum_N_sl),maxval(param%sum_N_sl),nIPneighbors,Nmembers),source=0.0_pREAL)
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allocate(dst%compatibility(2,maxval(param%sum_N_sl),maxval(param%sum_N_sl),nCellNeighbors,Nmembers),source=0.0_pREAL)
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end associate
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if (Nmembers > 0) call stateInit(ini,ph,Nmembers)
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@ -497,37 +491,9 @@ module function plastic_nonlocal_init() result(myPlasticity)
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end do
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allocate(compatibility(2,maxval(param%sum_N_sl),maxval(param%sum_N_sl),nIPneighbors,&
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allocate(compatibility(2,maxval(param%sum_N_sl),maxval(param%sum_N_sl),nCellNeighbors,&
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discretization_nIPs,discretization_Nelems), source=0.0_pREAL)
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! BEGIN DEPRECATED----------------------------------------------------------------------------------
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allocate(iRhoU(maxval(param%sum_N_sl),4,phases%length), source=0)
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allocate(iV(maxval(param%sum_N_sl),4,phases%length), source=0)
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do ph = 1, phases%length
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if (.not. myPlasticity(ph)) cycle
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phase => phases%get_dict(ph)
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Nmembers = count(material_ID_phase == ph)
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l = 0
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do t = 1,4
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do s = 1,param(ph)%sum_N_sl
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l = l + 1
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iRhoU(s,t,ph) = l
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end do
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end do
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l = l + (4+2+1)*param(ph)%sum_N_sl ! immobile(4), dipole(2), shear
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do t = 1,4
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do s = 1,param(ph)%sum_N_sl
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l = l + 1
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iV(s,t,ph) = l
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end do
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end do
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if (iV(param(ph)%sum_N_sl,4,ph) /= plasticState(ph)%sizeState) &
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error stop 'state indices not properly set (nonlocal)'
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end do
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end function plastic_nonlocal_init
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@ -541,9 +507,9 @@ module subroutine nonlocal_dependentState(ph, en)
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en
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integer :: &
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no, & !< neighbor offset
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neighbor_el, & ! element number of neighboring material point
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neighbor_ip, & ! integration point of neighboring material point
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en_nbr, & ! neighbor phase entry
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el_nbr, & ! element number of neighboring material point
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ip_nbr, & ! integration point of neighboring material point
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c, & ! index of dilsocation character (edge, screw)
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s, & ! slip system index
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dir, &
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@ -558,7 +524,7 @@ module subroutine nonlocal_dependentState(ph, en)
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real(pREAL), dimension(2) :: &
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rhoExcessGradient, &
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rhoExcessGradient_over_rho, &
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rhoTotal
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rho_sum
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real(pREAL), dimension(3) :: &
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rhoExcessDifferences, &
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normal_latticeConf
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@ -567,25 +533,23 @@ module subroutine nonlocal_dependentState(ph, en)
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invFp, & !< inverse of plastic deformation gradient
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connections, &
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invConnections
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real(pREAL), dimension(3,nIPneighbors) :: &
|
||||
real(pREAL), dimension(3,nCellNeighbors) :: &
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connection_latticeConf
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real(pREAL), dimension(2,param(ph)%sum_N_sl) :: &
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rhoExcess
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real(pREAL), dimension(param(ph)%sum_N_sl) :: &
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rho_edg_delta, &
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rho_scr_delta
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real(pREAL), dimension(param(ph)%sum_N_sl,10) :: &
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rho, &
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rho0, &
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rho_neighbor0
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rho_0, &
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rho_0_nbr
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real(pREAL), dimension(param(ph)%sum_N_sl,param(ph)%sum_N_sl) :: &
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myInteractionMatrix ! corrected slip interaction matrix
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real(pREAL), dimension(param(ph)%sum_N_sl,nIPneighbors) :: &
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rho_edg_delta_neighbor, &
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rho_scr_delta_neighbor
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real(pREAL), dimension(2,maxval(param%sum_N_sl),nIPneighbors) :: &
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neighbor_rhoExcess, & ! excess density at neighboring material point
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neighbor_rhoTotal ! total density at neighboring material point
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real(pREAL), dimension(param(ph)%sum_N_sl,nCellNeighbors) :: &
|
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rho_edg_delta_nbr, &
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rho_scr_delta_nbr
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real(pREAL), dimension(2,maxval(param%sum_N_sl),nCellNeighbors) :: &
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rho_delta_nbr, & ! excess density at neighboring material point
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rho_sum_nbr ! total density at neighboring material point
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real(pREAL), dimension(3,param(ph)%sum_N_sl,2) :: &
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m ! direction of dislocation motion
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|
@ -621,60 +585,57 @@ module subroutine nonlocal_dependentState(ph, en)
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! ToDo: MD: this is most likely only correct for F_i = I
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||||
!#################################################################################################
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|
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rho0 = getRho0(ph,en)
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rho_0 = getRho0(ph,en)
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if (plasticState(ph)%nonlocal .and. prm%shortRangeStressCorrection) then
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invFp = math_inv33(phase_mechanical_Fp(ph)%data(1:3,1:3,en))
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invFe = math_inv33(phase_mechanical_Fe(ph)%data(1:3,1:3,en))
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rho_edg_delta = rho0(:,mob_edg_pos) - rho0(:,mob_edg_neg)
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rho_scr_delta = rho0(:,mob_scr_pos) - rho0(:,mob_scr_neg)
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rho_edg_delta = rho_0(:,mob_edg_pos) - rho_0(:,mob_edg_neg)
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rho_scr_delta = rho_0(:,mob_scr_pos) - rho_0(:,mob_scr_neg)
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rhoExcess(1,:) = rho_edg_delta
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rhoExcess(2,:) = rho_scr_delta
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|
||||
FVsize = geom(ph)%V_0(en)**(1.0_pREAL/3.0_pREAL)
|
||||
FVsize = geom(ph)%v_0(en)**(1.0_pREAL/3.0_pREAL)
|
||||
|
||||
!* loop through my neighborhood and get the connection vectors (in lattice frame) and the excess densities
|
||||
|
||||
nRealNeighbors = 0.0_pREAL
|
||||
neighbor_rhoTotal = 0.0_pREAL
|
||||
do n = 1,nIPneighbors
|
||||
neighbor_el = geom(ph)%IPneighborhood(1,n,en)
|
||||
neighbor_ip = geom(ph)%IPneighborhood(2,n,en)
|
||||
rho_sum_nbr = 0.0_pREAL
|
||||
do n = 1,nCellNeighbors
|
||||
el_nbr = geom(ph)%IPneighborhood(1,n,en)
|
||||
ip_nbr = geom(ph)%IPneighborhood(2,n,en)
|
||||
|
||||
if (neighbor_el > 0 .and. neighbor_ip > 0) then
|
||||
if (material_ID_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip) == ph) then
|
||||
no = material_entry_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
|
||||
if (el_nbr > 0 .and. ip_nbr > 0) then
|
||||
if (material_ID_phase(1,(el_nbr-1)*discretization_nIPs + ip_nbr) == ph) then
|
||||
en_nbr = material_entry_phase(1,(el_nbr-1)*discretization_nIPs + ip_nbr)
|
||||
nRealNeighbors = nRealNeighbors + 1.0_pREAL
|
||||
rho_neighbor0 = getRho0(ph,no)
|
||||
rho_0_nbr = getRho0(ph,en_nbr)
|
||||
|
||||
rho_edg_delta_neighbor(:,n) = rho_neighbor0(:,mob_edg_pos) - rho_neighbor0(:,mob_edg_neg)
|
||||
rho_scr_delta_neighbor(:,n) = rho_neighbor0(:,mob_scr_pos) - rho_neighbor0(:,mob_scr_neg)
|
||||
rho_edg_delta_nbr(:,n) = rho_0_nbr(:,mob_edg_pos) - rho_0_nbr(:,mob_edg_neg)
|
||||
rho_scr_delta_nbr(:,n) = rho_0_nbr(:,mob_scr_pos) - rho_0_nbr(:,mob_scr_neg)
|
||||
|
||||
neighbor_rhoTotal(1,:,n) = sum(abs(rho_neighbor0(:,edg)),2)
|
||||
neighbor_rhoTotal(2,:,n) = sum(abs(rho_neighbor0(:,scr)),2)
|
||||
rho_sum_nbr(1,:,n) = sum(abs(rho_0_nbr(:,edg)),2)
|
||||
rho_sum_nbr(2,:,n) = sum(abs(rho_0_nbr(:,scr)),2)
|
||||
|
||||
connection_latticeConf(1:3,n) = matmul(invFe, geom(ph)%IPcoordinates(1:3,no) &
|
||||
- geom(ph)%IPcoordinates(1:3,en))
|
||||
normal_latticeConf = matmul(transpose(invFp), geom(ph)%IPareaNormal(1:3,n,en))
|
||||
connection_latticeConf(1:3,n) = matmul(invFe, geom(ph)%x_0(1:3,en_nbr) &
|
||||
- geom(ph)%x_0(1:3,en))
|
||||
normal_latticeConf = matmul(transpose(invFp), geom(ph)%n_0(1:3,n,en))
|
||||
if (math_inner(normal_latticeConf,connection_latticeConf(1:3,n)) < 0.0_pREAL) & ! neighboring connection points in opposite direction to face normal: must be periodic image
|
||||
connection_latticeConf(1:3,n) = normal_latticeConf * geom(ph)%V_0(en)/geom(ph)%IParea(n,en) ! instead take the surface normal scaled with the diameter of the cell
|
||||
connection_latticeConf(1:3,n) = normal_latticeConf * geom(ph)%v_0(en)/geom(ph)%a_0(n,en) ! instead take the surface normal scaled with the diameter of the cell
|
||||
else
|
||||
! local neighbor or different lattice structure or different constitution instance -> use central values instead
|
||||
connection_latticeConf(1:3,n) = 0.0_pREAL
|
||||
rho_edg_delta_neighbor(:,n) = rho_edg_delta
|
||||
rho_scr_delta_neighbor(:,n) = rho_scr_delta
|
||||
rho_edg_delta_nbr(:,n) = rho_edg_delta
|
||||
rho_scr_delta_nbr(:,n) = rho_scr_delta
|
||||
end if
|
||||
else
|
||||
! free surface -> use central values instead
|
||||
connection_latticeConf(1:3,n) = 0.0_pREAL
|
||||
rho_edg_delta_neighbor(:,n) = rho_edg_delta
|
||||
rho_scr_delta_neighbor(:,n) = rho_scr_delta
|
||||
rho_edg_delta_nbr(:,n) = rho_edg_delta
|
||||
rho_scr_delta_nbr(:,n) = rho_scr_delta
|
||||
end if
|
||||
end do
|
||||
|
||||
neighbor_rhoExcess(1,:,:) = rho_edg_delta_neighbor
|
||||
neighbor_rhoExcess(2,:,:) = rho_scr_delta_neighbor
|
||||
rho_delta_nbr(1,:,:) = rho_edg_delta_nbr
|
||||
rho_delta_nbr(2,:,:) = rho_scr_delta_nbr
|
||||
|
||||
!* loop through the slip systems and calculate the dislocation gradient by
|
||||
!* 1. interpolation of the excess density in the neighorhood
|
||||
|
@ -691,8 +652,8 @@ module subroutine nonlocal_dependentState(ph, en)
|
|||
neighbors(2) = 2 * dir
|
||||
connections(dir,1:3) = connection_latticeConf(1:3,neighbors(1)) &
|
||||
- connection_latticeConf(1:3,neighbors(2))
|
||||
rhoExcessDifferences(dir) = neighbor_rhoExcess(c,s,neighbors(1)) &
|
||||
- neighbor_rhoExcess(c,s,neighbors(2))
|
||||
rhoExcessDifferences(dir) = rho_delta_nbr(c,s,neighbors(1)) &
|
||||
- rho_delta_nbr(c,s,neighbors(2))
|
||||
end do
|
||||
invConnections = math_inv33(connections)
|
||||
if (all(dEq0(invConnections))) call IO_error(-1,ext_msg='back stress calculation: inversion error')
|
||||
|
@ -705,11 +666,11 @@ module subroutine nonlocal_dependentState(ph, en)
|
|||
rhoExcessGradient(2) = rhoExcessGradient(2) + sum(rho(s,imm_scr)) / FVsize
|
||||
|
||||
! ... normalized with the total density ...
|
||||
rhoTotal(1) = (sum(abs(rho(s,edg))) + sum(neighbor_rhoTotal(1,s,:))) / (1.0_pREAL + nRealNeighbors)
|
||||
rhoTotal(2) = (sum(abs(rho(s,scr))) + sum(neighbor_rhoTotal(2,s,:))) / (1.0_pREAL + nRealNeighbors)
|
||||
rho_sum(1) = (sum(abs(rho(s,edg))) + sum(rho_sum_nbr(1,s,:))) / (1.0_pREAL + nRealNeighbors)
|
||||
rho_sum(2) = (sum(abs(rho(s,scr))) + sum(rho_sum_nbr(2,s,:))) / (1.0_pREAL + nRealNeighbors)
|
||||
|
||||
rhoExcessGradient_over_rho = 0.0_pREAL
|
||||
where(rhoTotal > 0.0_pREAL) rhoExcessGradient_over_rho = rhoExcessGradient / rhoTotal
|
||||
where(rho_sum > 0.0_pREAL) rhoExcessGradient_over_rho = rhoExcessGradient / rho_sum
|
||||
|
||||
! ... gives the local stress correction when multiplied with a factor
|
||||
dst%tau_back(s,en) = - mu * prm%b_sl(s) / (2.0_pREAL * PI) &
|
||||
|
@ -743,7 +704,7 @@ module subroutine nonlocal_LpAndItsTangent(Lp,dLp_dMp, &
|
|||
t, & !< dislocation type
|
||||
s !< index of my current slip system
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,8) :: &
|
||||
rhoSgl !< single dislocation densities (including blocked)
|
||||
rho_sgl !< single dislocation densities (including blocked)
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,10) :: &
|
||||
rho
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,4) :: &
|
||||
|
@ -766,7 +727,7 @@ module subroutine nonlocal_LpAndItsTangent(Lp,dLp_dMp, &
|
|||
|
||||
!*** shortcut to state variables
|
||||
rho = getRho(ph,en)
|
||||
rhoSgl = rho(:,sgl)
|
||||
rho_sgl = rho(:,sgl)
|
||||
|
||||
do s = 1,prm%sum_N_sl
|
||||
tau(s) = math_tensordot(Mp, prm%P_sl(1:3,1:3,s))
|
||||
|
@ -799,20 +760,20 @@ module subroutine nonlocal_LpAndItsTangent(Lp,dLp_dMp, &
|
|||
stt%v(:,en) = pack(v,.true.)
|
||||
|
||||
!*** Bauschinger effect
|
||||
forall (s = 1:prm%sum_N_sl, t = 5:8, rhoSgl(s,t) * v(s,t-4) < 0.0_pREAL) &
|
||||
rhoSgl(s,t-4) = rhoSgl(s,t-4) + abs(rhoSgl(s,t))
|
||||
forall (s = 1:prm%sum_N_sl, t = 5:8, rho_sgl(s,t) * v(s,t-4) < 0.0_pREAL) &
|
||||
rho_sgl(s,t-4) = rho_sgl(s,t-4) + abs(rho_sgl(s,t))
|
||||
|
||||
dot_gamma = sum(rhoSgl(:,1:4) * v, 2) * prm%b_sl
|
||||
dot_gamma = sum(rho_sgl(:,1:4) * v, 2) * prm%b_sl
|
||||
|
||||
do s = 1,prm%sum_N_sl
|
||||
Lp = Lp + dot_gamma(s) * prm%P_sl(1:3,1:3,s)
|
||||
forall (i=1:3,j=1:3,k=1:3,l=1:3) &
|
||||
dLp_dMp(i,j,k,l) = dLp_dMp(i,j,k,l) &
|
||||
+ prm%P_sl(i,j,s) * prm%P_sl(k,l,s) &
|
||||
* sum(rhoSgl(s,1:4) * dv_dtau(s,1:4)) * prm%b_sl(s) &
|
||||
* sum(rho_sgl(s,1:4) * dv_dtau(s,1:4)) * prm%b_sl(s) &
|
||||
+ prm%P_sl(i,j,s) &
|
||||
* (+ prm%P_nS_pos(k,l,s) * rhoSgl(s,3) * dv_dtauNS(s,3) &
|
||||
- prm%P_nS_neg(k,l,s) * rhoSgl(s,4) * dv_dtauNS(s,4)) * prm%b_sl(s)
|
||||
* (+ prm%P_nS_pos(k,l,s) * rho_sgl(s,3) * dv_dtauNS(s,3) &
|
||||
- prm%P_nS_neg(k,l,s) * rho_sgl(s,4) * dv_dtauNS(s,4)) * prm%b_sl(s)
|
||||
end do
|
||||
|
||||
end associate
|
||||
|
@ -848,7 +809,7 @@ module subroutine plastic_nonlocal_deltaState(Mp,ph,en)
|
|||
real(pREAL), dimension(param(ph)%sum_N_sl) :: &
|
||||
tau ! current resolved shear stress
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,2) :: &
|
||||
rhoDip, & ! current dipole dislocation densities (screw and edge dipoles)
|
||||
rho_dip, & ! current dipole dislocation densities (screw and edge dipoles)
|
||||
dUpper, & ! current maximum stable dipole distance for edges and screws
|
||||
dUpperOld, & ! old maximum stable dipole distance for edges and screws
|
||||
deltaDUpper ! change in maximum stable dipole distance for edges and screws
|
||||
|
@ -864,7 +825,7 @@ module subroutine plastic_nonlocal_deltaState(Mp,ph,en)
|
|||
dUpperOld = reshape(dst%max_dipole_height(:,en),[prm%sum_N_sl,2])
|
||||
|
||||
rho = getRho(ph,en)
|
||||
rhoDip = rho(:,dip)
|
||||
rho_dip = rho(:,dip)
|
||||
|
||||
!****************************************************************************
|
||||
!*** dislocation remobilization (bauschinger effect)
|
||||
|
@ -904,7 +865,7 @@ module subroutine plastic_nonlocal_deltaState(Mp,ph,en)
|
|||
deltaRhoDipole2SingleStress = 0.0_pREAL
|
||||
forall (c=1:2, s=1:prm%sum_N_sl, deltaDUpper(s,c) < 0.0_pREAL .and. &
|
||||
dNeq0(dUpperOld(s,c) - prm%minDipoleHeight(s,c))) &
|
||||
deltaRhoDipole2SingleStress(s,8+c) = rhoDip(s,c) * deltaDUpper(s,c) &
|
||||
deltaRhoDipole2SingleStress(s,8+c) = rho_dip(s,c) * deltaDUpper(s,c) &
|
||||
/ (dUpperOld(s,c) - prm%minDipoleHeight(s,c))
|
||||
|
||||
forall (t=1:4) deltaRhoDipole2SingleStress(:,t) = -0.5_pREAL * deltaRhoDipole2SingleStress(:,(t-1)/2+9)
|
||||
|
@ -934,28 +895,24 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
|
||||
integer :: &
|
||||
c, & !< character of dislocation
|
||||
t, & !< type of dislocation
|
||||
s !< index of my current slip system
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,10) :: &
|
||||
rho, &
|
||||
rho0, & !< dislocation density at beginning of time step
|
||||
rhoDot, & !< density evolution
|
||||
rhoDotMultiplication, & !< density evolution by multiplication
|
||||
rhoDotSingle2DipoleGlide, & !< density evolution by dipole formation (by glide)
|
||||
rhoDotAthermalAnnihilation, & !< density evolution by athermal annihilation
|
||||
rhoDotThermalAnnihilation !< density evolution by thermal annihilation
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,8) :: &
|
||||
rhoSgl, & !< current single dislocation densities (positive/negative screw and edge without dipoles)
|
||||
my_rhoSgl0 !< single dislocation densities of central ip (positive/negative screw and edge without dipoles)
|
||||
rho_sgl !< current single dislocation densities (positive/negative screw and edge without dipoles)
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,4) :: &
|
||||
v, & !< current dislocation glide velocity
|
||||
v0, &
|
||||
dot_gamma !< shear rates
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl) :: &
|
||||
tau, & !< current resolved shear stress
|
||||
v_climb !< climb velocity of edge dipoles
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,2) :: &
|
||||
rhoDip, & !< current dipole dislocation densities (screw and edge dipoles)
|
||||
rho_dip, & !< current dipole dislocation densities (screw and edge dipoles)
|
||||
dLower, & !< minimum stable dipole distance for edges and screws
|
||||
dUpper !< current maximum stable dipole distance for edges and screws
|
||||
real(pREAL) :: &
|
||||
|
@ -978,14 +935,12 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
tau = 0.0_pREAL
|
||||
dot_gamma = 0.0_pREAL
|
||||
|
||||
rho = getRho(ph,en)
|
||||
rhoSgl = rho(:,sgl)
|
||||
rhoDip = rho(:,dip)
|
||||
rho0 = getRho0(ph,en)
|
||||
my_rhoSgl0 = rho0(:,sgl)
|
||||
rho = getRho(ph,en)
|
||||
rho_sgl = rho(:,sgl)
|
||||
rho_dip = rho(:,dip)
|
||||
|
||||
v = reshape(stt%v(:,en),[prm%sum_N_sl,4])
|
||||
dot_gamma = rhoSgl(:,1:4) * v * spread(prm%b_sl,2,4)
|
||||
dot_gamma = rho_sgl(:,1:4) * v * spread(prm%b_sl,2,4)
|
||||
|
||||
|
||||
! limits for stable dipole height
|
||||
|
@ -1024,8 +979,6 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
* sqrt(dst%rho_forest(:,en)) / prm%i_sl / prm%b_sl, 2, 4) ! eq. 3.26
|
||||
end if isBCC
|
||||
|
||||
v0 = reshape(st0%v(:,en),[prm%sum_N_sl,4])
|
||||
|
||||
|
||||
!****************************************************************************
|
||||
! dipole formation and annihilation
|
||||
|
@ -1033,20 +986,20 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
! formation by glide
|
||||
do c = 1,2
|
||||
rhoDotSingle2DipoleGlide(:,2*c-1) = -2.0_pREAL * dUpper(:,c) / prm%b_sl &
|
||||
* ( rhoSgl(:,2*c-1) * abs(dot_gamma(:,2*c)) & ! negative mobile --> positive mobile
|
||||
+ rhoSgl(:,2*c) * abs(dot_gamma(:,2*c-1)) & ! positive mobile --> negative mobile
|
||||
+ abs(rhoSgl(:,2*c+4)) * abs(dot_gamma(:,2*c-1))) ! positive mobile --> negative immobile
|
||||
* ( rho_sgl(:,2*c-1) * abs(dot_gamma(:,2*c)) & ! negative mobile --> positive mobile
|
||||
+ rho_sgl(:,2*c) * abs(dot_gamma(:,2*c-1)) & ! positive mobile --> negative mobile
|
||||
+ abs(rho_sgl(:,2*c+4)) * abs(dot_gamma(:,2*c-1))) ! positive mobile --> negative immobile
|
||||
|
||||
rhoDotSingle2DipoleGlide(:,2*c) = -2.0_pREAL * dUpper(:,c) / prm%b_sl &
|
||||
* ( rhoSgl(:,2*c-1) * abs(dot_gamma(:,2*c)) & ! negative mobile --> positive mobile
|
||||
+ rhoSgl(:,2*c) * abs(dot_gamma(:,2*c-1)) & ! positive mobile --> negative mobile
|
||||
+ abs(rhoSgl(:,2*c+3)) * abs(dot_gamma(:,2*c))) ! negative mobile --> positive immobile
|
||||
* ( rho_sgl(:,2*c-1) * abs(dot_gamma(:,2*c)) & ! negative mobile --> positive mobile
|
||||
+ rho_sgl(:,2*c) * abs(dot_gamma(:,2*c-1)) & ! positive mobile --> negative mobile
|
||||
+ abs(rho_sgl(:,2*c+3)) * abs(dot_gamma(:,2*c))) ! negative mobile --> positive immobile
|
||||
|
||||
rhoDotSingle2DipoleGlide(:,2*c+3) = -2.0_pREAL * dUpper(:,c) / prm%b_sl &
|
||||
* rhoSgl(:,2*c+3) * abs(dot_gamma(:,2*c)) ! negative mobile --> positive immobile
|
||||
* rho_sgl(:,2*c+3) * abs(dot_gamma(:,2*c)) ! negative mobile --> positive immobile
|
||||
|
||||
rhoDotSingle2DipoleGlide(:,2*c+4) = -2.0_pREAL * dUpper(:,c) / prm%b_sl &
|
||||
* rhoSgl(:,2*c+4) * abs(dot_gamma(:,2*c-1)) ! positive mobile --> negative immobile
|
||||
* rho_sgl(:,2*c+4) * abs(dot_gamma(:,2*c-1)) ! positive mobile --> negative immobile
|
||||
|
||||
rhoDotSingle2DipoleGlide(:,c+8) = abs(rhoDotSingle2DipoleGlide(:,2*c+3)) &
|
||||
+ abs(rhoDotSingle2DipoleGlide(:,2*c+4)) &
|
||||
|
@ -1059,9 +1012,9 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
rhoDotAthermalAnnihilation = 0.0_pREAL
|
||||
forall (c=1:2) &
|
||||
rhoDotAthermalAnnihilation(:,c+8) = -2.0_pREAL * dLower(:,c) / prm%b_sl &
|
||||
* ( 2.0_pREAL * (rhoSgl(:,2*c-1) * abs(dot_gamma(:,2*c)) + rhoSgl(:,2*c) * abs(dot_gamma(:,2*c-1))) & ! was single hitting single
|
||||
+ 2.0_pREAL * (abs(rhoSgl(:,2*c+3)) * abs(dot_gamma(:,2*c)) + abs(rhoSgl(:,2*c+4)) * abs(dot_gamma(:,2*c-1))) & ! was single hitting immobile single or was immobile single hit by single
|
||||
+ rhoDip(:,c) * (abs(dot_gamma(:,2*c-1)) + abs(dot_gamma(:,2*c)))) ! single knocks dipole constituent
|
||||
* ( 2.0_pREAL * (rho_sgl(:,2*c-1) * abs(dot_gamma(:,2*c)) + rho_sgl(:,2*c) * abs(dot_gamma(:,2*c-1))) & ! was single hitting single
|
||||
+ 2.0_pREAL * (abs(rho_sgl(:,2*c+3)) * abs(dot_gamma(:,2*c)) + abs(rho_sgl(:,2*c+4)) * abs(dot_gamma(:,2*c-1))) & ! was single hitting immobile single or was immobile single hit by single
|
||||
+ rho_dip(:,c) * (abs(dot_gamma(:,2*c-1)) + abs(dot_gamma(:,2*c)))) ! single knocks dipole constituent
|
||||
|
||||
! annihilated screw dipoles leave edge jogs behind on the colinear system
|
||||
if (phase_lattice(ph) == 'cF') &
|
||||
|
@ -1076,8 +1029,8 @@ module subroutine nonlocal_dotState(Mp,timestep, &
|
|||
v_climb = D_SD * mu * prm%V_at &
|
||||
/ (PI * (1.0_pREAL-nu) * (dUpper(:,1) + dLower(:,1)) * K_B * Temperature) ! eq. 3.54
|
||||
forall (s = 1:prm%sum_N_sl, dUpper(s,1) > dLower(s,1)) &
|
||||
rhoDotThermalAnnihilation(s,9) = max(- 4.0_pREAL * rhoDip(s,1) * v_climb(s) / (dUpper(s,1) - dLower(s,1)), &
|
||||
- rhoDip(s,1) / timestep - rhoDotAthermalAnnihilation(s,9) &
|
||||
rhoDotThermalAnnihilation(s,9) = max(- 4.0_pREAL * rho_dip(s,1) * v_climb(s) / (dUpper(s,1) - dLower(s,1)), &
|
||||
- rho_dip(s,1) / timestep - rhoDotAthermalAnnihilation(s,9) &
|
||||
- rhoDotSingle2DipoleGlide(s,9)) ! make sure that we do not annihilate more dipoles than we have
|
||||
|
||||
rhoDot = rhoDotFlux(timestep, ph,en) &
|
||||
|
@ -1118,38 +1071,36 @@ function rhoDotFlux(timestep,ph,en)
|
|||
ns, & !< short notation for the total number of active slip systems
|
||||
c, & !< character of dislocation
|
||||
n, & !< index of my current neighbor
|
||||
neighbor_el, & !< element number of my neighbor
|
||||
neighbor_ip, & !< integration point of my neighbor
|
||||
neighbor_n, & !< neighbor index pointing to en when looking from my neighbor
|
||||
el_nbr, & !< element number of my neighbor
|
||||
ip_nbr, & !< integration point of my neighbor
|
||||
n_nbr, & !< neighbor index pointing to en when looking from my neighbor
|
||||
opposite_neighbor, & !< index of my opposite neighbor
|
||||
opposite_ip, & !< ip of my opposite neighbor
|
||||
opposite_el, & !< element index of my opposite neighbor
|
||||
opposite_n, & !< neighbor index pointing to en when looking from my opposite neighbor
|
||||
t, & !< type of dislocation
|
||||
no,& !< neighbor offset shortcut
|
||||
np,& !< neighbor phase shortcut
|
||||
en_nbr,& !< neighbor phase entry
|
||||
ph_nbr,& !< neighbor phase ID
|
||||
topp, & !< type of dislocation with opposite sign to t
|
||||
s !< index of my current slip system
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,10) :: &
|
||||
rho, &
|
||||
rho0, & !< dislocation density at beginning of time step
|
||||
rho_0, & !< dislocation density at beginning of time step
|
||||
rhoDotFlux !< density evolution by flux
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,8) :: &
|
||||
rhoSgl, & !< current single dislocation densities (positive/negative screw and edge without dipoles)
|
||||
neighbor_rhoSgl0, & !< current single dislocation densities of neighboring ip (positive/negative screw and edge without dipoles)
|
||||
my_rhoSgl0 !< single dislocation densities of central ip (positive/negative screw and edge without dipoles)
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,4) :: &
|
||||
v, & !< current dislocation glide velocity
|
||||
v0, &
|
||||
neighbor_v0, & !< dislocation glide velocity of enighboring ip
|
||||
dot_gamma !< shear rates
|
||||
rho_0_sgl_mob, & !< mobile dislocation densities of neighboring ip (positive/negative screw and edge)
|
||||
rho_0_sgl_mob_nbr, & !< mobile dislocation densities of neighboring ip (positive/negative screw and edge)
|
||||
v, & !< dislocation glide velocity
|
||||
v_0, &
|
||||
v_0_nbr, & !< dislocation glide velocity of enighboring ip
|
||||
dot_gamma !< shear rates
|
||||
real(pREAL), dimension(3,param(ph)%sum_N_sl,4) :: &
|
||||
m !< direction of dislocation motion
|
||||
real(pREAL), dimension(3,3) :: &
|
||||
my_F, & !< my total deformation gradient
|
||||
neighbor_F, & !< total deformation gradient of my neighbor
|
||||
F_nbr, & !< total deformation gradient of my neighbor
|
||||
my_Fe, & !< my elastic deformation gradient
|
||||
neighbor_Fe, & !< elastic deformation gradient of my neighbor
|
||||
F_e_nbr, & !< elastic deformation gradient of my neighbor
|
||||
Favg !< average total deformation gradient of en and my neighbor
|
||||
real(pREAL), dimension(3) :: &
|
||||
normal_neighbor2me, & !< interface normal pointing from my neighbor to en in neighbor's lattice configuration
|
||||
|
@ -1157,7 +1108,7 @@ function rhoDotFlux(timestep,ph,en)
|
|||
normal_me2neighbor, & !< interface normal pointing from en to my neighbor in my lattice configuration
|
||||
normal_me2neighbor_defConf !< interface normal pointing from en to my neighbor in shared deformed configuration
|
||||
real(pREAL) :: &
|
||||
area, & !< area of the current interface
|
||||
a, & !< area of the current interface
|
||||
transmissivity, & !< overall transmissivity of dislocation flux to neighboring material point
|
||||
lineLength !< dislocation line length leaving the current interface
|
||||
|
||||
|
@ -1166,19 +1117,19 @@ function rhoDotFlux(timestep,ph,en)
|
|||
dst => dependentState(ph), &
|
||||
stt => state(ph), &
|
||||
st0 => state0(ph))
|
||||
|
||||
ns = prm%sum_N_sl
|
||||
|
||||
dot_gamma = 0.0_pREAL
|
||||
|
||||
rho = getRho(ph,en)
|
||||
rhoSgl = rho(:,sgl)
|
||||
rho0 = getRho0(ph,en)
|
||||
my_rhoSgl0 = rho0(:,sgl)
|
||||
rho = getRho(ph,en)
|
||||
rho_0 = getRho0(ph,en)
|
||||
rho_0_sgl_mob = rho_0(:,mob)
|
||||
|
||||
v = reshape(stt%v(:,en),[prm%sum_N_sl,4]) !ToDo: MD: I think we should use state0 here
|
||||
dot_gamma = rhoSgl(:,1:4) * v * spread(prm%b_sl,2,4)
|
||||
dot_gamma = rho(:,mob) * v * spread(prm%b_sl,2,4)
|
||||
|
||||
v0 = reshape(st0%v(:,en),[prm%sum_N_sl,4])
|
||||
v_0 = reshape(st0%v(:,en),[prm%sum_N_sl,4])
|
||||
|
||||
!****************************************************************************
|
||||
!*** calculate dislocation fluxes (only for nonlocal plasticity)
|
||||
|
@ -1187,8 +1138,8 @@ function rhoDotFlux(timestep,ph,en)
|
|||
|
||||
!*** check CFL (Courant-Friedrichs-Lewy) condition for flux
|
||||
if (any( abs(dot_gamma) > 0.0_pREAL & ! any active slip system ...
|
||||
.and. prm%C_CFL * abs(v0) * timestep &
|
||||
> geom(ph)%V_0(en)/ maxval(geom(ph)%IParea(:,en)))) then ! ...with velocity above critical value (we use the reference volume and area for simplicity here)
|
||||
.and. prm%C_CFL * abs(v_0) * timestep &
|
||||
> geom(ph)%v_0(en)/ maxval(geom(ph)%a_0(:,en)))) then ! ...with velocity above critical value (we use the reference volume and area for simplicity here)
|
||||
rhoDotFlux = IEEE_value(1.0_pREAL,IEEE_quiet_NaN) ! enforce cutback
|
||||
return
|
||||
end if
|
||||
|
@ -1205,28 +1156,28 @@ function rhoDotFlux(timestep,ph,en)
|
|||
my_F = phase_mechanical_F(ph)%data(1:3,1:3,en)
|
||||
my_Fe = matmul(my_F, math_inv33(phase_mechanical_Fp(ph)%data(1:3,1:3,en)))
|
||||
|
||||
neighbors: do n = 1,nIPneighbors
|
||||
neighbors: do n = 1,nCellNeighbors
|
||||
|
||||
neighbor_el = geom(ph)%IPneighborhood(1,n,en)
|
||||
neighbor_ip = geom(ph)%IPneighborhood(2,n,en)
|
||||
neighbor_n = geom(ph)%IPneighborhood(3,n,en)
|
||||
np = material_ID_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
|
||||
no = material_entry_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
|
||||
el_nbr = geom(ph)%IPneighborhood(1,n,en)
|
||||
ip_nbr = geom(ph)%IPneighborhood(2,n,en)
|
||||
n_nbr = geom(ph)%IPneighborhood(3,n,en)
|
||||
ph_nbr = material_ID_phase(1,(el_nbr-1)*discretization_nIPs + ip_nbr)
|
||||
en_nbr = material_entry_phase(1,(el_nbr-1)*discretization_nIPs + ip_nbr)
|
||||
|
||||
opposite_neighbor = n + mod(n,2) - mod(n+1,2)
|
||||
opposite_el = geom(ph)%IPneighborhood(1,opposite_neighbor,en)
|
||||
opposite_ip = geom(ph)%IPneighborhood(2,opposite_neighbor,en)
|
||||
opposite_n = geom(ph)%IPneighborhood(3,opposite_neighbor,en)
|
||||
|
||||
if (neighbor_n > 0) then ! if neighbor exists, average deformation gradient
|
||||
neighbor_F = phase_mechanical_F(np)%data(1:3,1:3,no)
|
||||
neighbor_Fe = matmul(neighbor_F, math_inv33(phase_mechanical_Fp(np)%data(1:3,1:3,no)))
|
||||
Favg = 0.5_pREAL * (my_F + neighbor_F)
|
||||
if (n_nbr > 0) then ! if neighbor exists, average deformation gradient
|
||||
F_nbr = phase_mechanical_F(ph_nbr)%data(1:3,1:3,en_nbr)
|
||||
F_e_nbr = matmul(F_nbr, math_inv33(phase_mechanical_Fp(ph_nbr)%data(1:3,1:3,en_nbr)))
|
||||
Favg = 0.5_pREAL * (my_F + F_nbr)
|
||||
else ! if no neighbor, take my value as average
|
||||
Favg = my_F
|
||||
end if
|
||||
|
||||
neighbor_v0 = 0.0_pREAL ! needed for check of sign change in flux density below
|
||||
v_0_nbr = 0.0_pREAL ! needed for check of sign change in flux density below
|
||||
|
||||
!* FLUX FROM MY NEIGHBOR TO ME
|
||||
!* This is only considered, if I have a neighbor of nonlocal plasticity
|
||||
|
@ -1236,38 +1187,37 @@ function rhoDotFlux(timestep,ph,en)
|
|||
!* my neighbor's interface.
|
||||
!* The entering flux from my neighbor will be distributed on my slip systems according to the
|
||||
!* compatibility
|
||||
if (neighbor_n > 0) then
|
||||
if (mechanical_plasticity_type(np) == MECHANICAL_PLASTICITY_NONLOCAL .and. &
|
||||
if (n_nbr > 0) then
|
||||
if (mechanical_plasticity_type(ph_nbr) == MECHANICAL_PLASTICITY_NONLOCAL .and. &
|
||||
any(dependentState(ph)%compatibility(:,:,:,n,en) > 0.0_pREAL)) then
|
||||
|
||||
forall (s = 1:ns, t = 1:4)
|
||||
neighbor_v0(s,t) = plasticState(np)%state0(iV (s,t,np),no)
|
||||
neighbor_rhoSgl0(s,t) = max(plasticState(np)%state0(iRhoU(s,t,np),no),0.0_pREAL)
|
||||
endforall
|
||||
! ToDo MD: Not sure if ns is correct here, but I think that compatibility is 0 if different phase
|
||||
v_0_nbr = reshape(state0(ph_nbr)%v(:,en_nbr),[ns,4])
|
||||
rho_0_sgl_mob_nbr = max(reshape(state0(ph_nbr)%rho_sgl_mob(:,en_nbr),[ns,4]),0.0_pREAL)
|
||||
|
||||
where (neighbor_rhoSgl0 * IPvolume(neighbor_ip,neighbor_el) ** 0.667_pREAL < prm%rho_min &
|
||||
.or. neighbor_rhoSgl0 < prm%rho_significant) &
|
||||
neighbor_rhoSgl0 = 0.0_pREAL
|
||||
where (rho_0_sgl_mob_nbr * geom(ph_nbr)%v_0(en_nbr) ** 0.667_pREAL < prm%rho_min &
|
||||
.or. rho_0_sgl_mob_nbr < prm%rho_significant) &
|
||||
rho_0_sgl_mob_nbr = 0.0_pREAL
|
||||
normal_neighbor2me_defConf = math_det33(Favg) * matmul(math_inv33(transpose(Favg)), &
|
||||
IPareaNormal(1:3,neighbor_n,neighbor_ip,neighbor_el)) ! normal of the interface in (average) deformed configuration (pointing neighbor => en)
|
||||
normal_neighbor2me = matmul(transpose(neighbor_Fe), normal_neighbor2me_defConf) &
|
||||
/ math_det33(neighbor_Fe) ! interface normal in the lattice configuration of my neighbor
|
||||
area = IParea(neighbor_n,neighbor_ip,neighbor_el) * norm2(normal_neighbor2me)
|
||||
geom(ph_nbr)%n_0(1:3,n_nbr,en_nbr)) ! normal of the interface in (average) deformed configuration (pointing neighbor => en)
|
||||
normal_neighbor2me = matmul(transpose(F_e_nbr), normal_neighbor2me_defConf) &
|
||||
/ math_det33(F_e_nbr) ! interface normal in the lattice configuration of my neighbor
|
||||
a = geom(ph_nbr)%a_0(n_nbr,en_nbr) * norm2(normal_neighbor2me)
|
||||
normal_neighbor2me = normal_neighbor2me / norm2(normal_neighbor2me) ! normalize the surface normal to unit length
|
||||
do s = 1,ns
|
||||
do t = 1,4
|
||||
c = (t + 1) / 2
|
||||
topp = t + mod(t,2) - mod(t+1,2)
|
||||
if (neighbor_v0(s,t) * math_inner(m(1:3,s,t), normal_neighbor2me) > 0.0_pREAL & ! flux from my neighbor to en == entering flux for en
|
||||
.and. v0(s,t) * neighbor_v0(s,t) >= 0.0_pREAL ) then ! ... only if no sign change in flux density
|
||||
lineLength = neighbor_rhoSgl0(s,t) * neighbor_v0(s,t) &
|
||||
* math_inner(m(1:3,s,t), normal_neighbor2me) * area ! positive line length that wants to enter through this interface
|
||||
if (v_0_nbr(s,t) * math_inner(m(1:3,s,t), normal_neighbor2me) > 0.0_pREAL & ! flux from my neighbor to en == entering flux for en
|
||||
.and. v_0(s,t) * v_0_nbr(s,t) >= 0.0_pREAL ) then ! ... only if no sign change in flux density
|
||||
lineLength = rho_0_sgl_mob_nbr(s,t) * v_0_nbr(s,t) &
|
||||
* math_inner(m(1:3,s,t), normal_neighbor2me) * a ! positive line length that wants to enter through this interface
|
||||
where (dependentState(ph)%compatibility(c,:,s,n,en) > 0.0_pREAL) &
|
||||
rhoDotFlux(:,t) = rhoDotFlux(1:ns,t) &
|
||||
+ lineLength/geom(ph)%V_0(en)*dependentState(ph)%compatibility(c,:,s,n,en)**2 ! transferring to equally signed mobile dislocation type
|
||||
+ lineLength/geom(ph)%v_0(en)*dependentState(ph)%compatibility(c,:,s,n,en)**2 ! transferring to equally signed mobile dislocation type
|
||||
where (dependentState(ph)%compatibility(c,:,s,n,en) < 0.0_pREAL) &
|
||||
rhoDotFlux(:,topp) = rhoDotFlux(:,topp) &
|
||||
+ lineLength/geom(ph)%V_0(en)*dependentState(ph)%compatibility(c,:,s,n,en)**2 ! transferring to opposite signed mobile dislocation type
|
||||
+ lineLength/geom(ph)%v_0(en)*dependentState(ph)%compatibility(c,:,s,n,en)**2 ! transferring to opposite signed mobile dislocation type
|
||||
|
||||
end if
|
||||
end do
|
||||
|
@ -1283,29 +1233,29 @@ function rhoDotFlux(timestep,ph,en)
|
|||
!* In case of reduced transmissivity, part of the leaving flux is stored as dead dislocation density.
|
||||
!* That means for an interface of zero transmissivity the leaving flux is fully converted to dead dislocations.
|
||||
if (opposite_n > 0) then
|
||||
if (mechanical_plasticity_type(np) == MECHANICAL_PLASTICITY_NONLOCAL) then
|
||||
if (mechanical_plasticity_type(ph_nbr) == MECHANICAL_PLASTICITY_NONLOCAL) then
|
||||
|
||||
normal_me2neighbor_defConf = math_det33(Favg) &
|
||||
* matmul(math_inv33(transpose(Favg)),geom(ph)%IPareaNormal(1:3,n,en)) ! normal of the interface in (average) deformed configuration (pointing en => neighbor)
|
||||
* matmul(math_inv33(transpose(Favg)),geom(ph)%n_0(1:3,n,en)) ! normal of the interface in (average) deformed configuration (pointing en => neighbor)
|
||||
normal_me2neighbor = matmul(transpose(my_Fe), normal_me2neighbor_defConf) &
|
||||
/ math_det33(my_Fe) ! interface normal in my lattice configuration
|
||||
area = geom(ph)%IParea(n,en) * norm2(normal_me2neighbor)
|
||||
a = geom(ph)%a_0(n,en) * norm2(normal_me2neighbor)
|
||||
normal_me2neighbor = normal_me2neighbor / norm2(normal_me2neighbor) ! normalize the surface normal to unit length
|
||||
do s = 1,ns
|
||||
do t = 1,4
|
||||
c = (t + 1) / 2
|
||||
if (v0(s,t) * math_inner(m(1:3,s,t), normal_me2neighbor) > 0.0_pREAL ) then ! flux from en to my neighbor == leaving flux for en (might also be a pure flux from my mobile density to dead density if interface not at all transmissive)
|
||||
if (v0(s,t) * neighbor_v0(s,t) >= 0.0_pREAL) then ! no sign change in flux density
|
||||
if (v_0(s,t) * math_inner(m(1:3,s,t), normal_me2neighbor) > 0.0_pREAL ) then ! flux from en to my neighbor == leaving flux for en (might also be a pure flux from my mobile density to dead density if interface not at all transmissive)
|
||||
if (v_0(s,t) * v_0_nbr(s,t) >= 0.0_pREAL) then ! no sign change in flux density
|
||||
transmissivity = sum(dependentState(ph)%compatibility(c,:,s,n,en)**2) ! overall transmissivity from this slip system to my neighbor
|
||||
else ! sign change in flux density means sign change in stress which does not allow for dislocations to arive at the neighbor
|
||||
transmissivity = 0.0_pREAL
|
||||
end if
|
||||
lineLength = my_rhoSgl0(s,t) * v0(s,t) &
|
||||
* math_inner(m(1:3,s,t), normal_me2neighbor) * area ! positive line length of mobiles that wants to leave through this interface
|
||||
rhoDotFlux(s,t) = rhoDotFlux(s,t) - lineLength / geom(ph)%V_0(en) ! subtract dislocation flux from current type
|
||||
lineLength = rho_0_sgl_mob(s,t) * v_0(s,t) &
|
||||
* math_inner(m(1:3,s,t), normal_me2neighbor) * a ! positive line length of mobiles that wants to leave through this interface
|
||||
rhoDotFlux(s,t) = rhoDotFlux(s,t) - lineLength / geom(ph)%v_0(en) ! subtract dislocation flux from current type
|
||||
rhoDotFlux(s,t+4) = rhoDotFlux(s,t+4) &
|
||||
+ lineLength / geom(ph)%V_0(en) * (1.0_pREAL - transmissivity) &
|
||||
* sign(1.0_pREAL, v0(s,t)) ! dislocation flux that is not able to leave through interface (because of low transmissivity) will remain as immobile single density at the material point
|
||||
+ lineLength / geom(ph)%v_0(en) * (1.0_pREAL - transmissivity) &
|
||||
* sign(1.0_pREAL, v_0(s,t)) ! dislocation flux that is not able to leave through interface (because of low transmissivity) will remain as immobile single density at the material point
|
||||
end if
|
||||
end do
|
||||
end do
|
||||
|
@ -1325,67 +1275,57 @@ end function rhoDotFlux
|
|||
! plane normals and signed cosine of the angle between the slip directions. Only the largest values
|
||||
! that sum up to a total of 1 are considered, all others are set to zero.
|
||||
!--------------------------------------------------------------------------------------------------
|
||||
module subroutine plastic_nonlocal_updateCompatibility(orientation,ce)
|
||||
module subroutine plastic_nonlocal_updateCompatibility(orientation,ph,en)
|
||||
|
||||
type(tRotationContainer), dimension(:), intent(in) :: &
|
||||
orientation ! crystal orientation
|
||||
integer, intent(in) :: &
|
||||
ce
|
||||
ph, en
|
||||
|
||||
integer :: &
|
||||
n, & ! neighbor index
|
||||
ph, &
|
||||
en, &
|
||||
ip, &
|
||||
el, &
|
||||
neighbor_e, & ! element index of my neighbor
|
||||
neighbor_i, & ! integration point index of my neighbor
|
||||
neighbor_me, &
|
||||
neighbor_phase, &
|
||||
el_nbr, & ! element index of my neighbor
|
||||
ip_nbr, & ! integration point index of my neighbor
|
||||
ce_nbr, &
|
||||
en_nbr, &
|
||||
ph_nbr, &
|
||||
ns, & ! number of active slip systems
|
||||
s1, & ! slip system index (en)
|
||||
s2 ! slip system index (my neighbor)
|
||||
real(pREAL), dimension(2,param(material_ID_phase(1,ce))%sum_N_sl,param(material_ID_phase(1,ce))%sum_N_sl,nIPneighbors) :: &
|
||||
real(pREAL), dimension(2,param(ph)%sum_N_sl,param(ph)%sum_N_sl,nCellNeighbors) :: &
|
||||
my_compatibility ! my_compatibility for current element and ip
|
||||
real(pREAL) :: &
|
||||
my_compatibilitySum, &
|
||||
thresholdValue, &
|
||||
nThresholdValues
|
||||
logical, dimension(param(material_ID_phase(1,ce))%sum_N_sl) :: &
|
||||
logical, dimension(param(ph)%sum_N_sl) :: &
|
||||
belowThreshold
|
||||
type(tRotation) :: mis
|
||||
|
||||
|
||||
ph = material_ID_phase(1,ce)
|
||||
el = (ce-1)/discretization_nIPs + 1
|
||||
ip = modulo(ce-1,discretization_nIPs) + 1
|
||||
|
||||
associate(prm => param(ph))
|
||||
ns = prm%sum_N_sl
|
||||
|
||||
en = material_entry_phase(1,(el-1)*discretization_nIPs + ip)
|
||||
!*** start out fully compatible
|
||||
my_compatibility = 0.0_pREAL
|
||||
forall(s1 = 1:ns) my_compatibility(:,s1,s1,:) = 1.0_pREAL
|
||||
|
||||
neighbors: do n = 1,nIPneighbors
|
||||
neighbor_e = IPneighborhood(1,n,ip,el)
|
||||
neighbor_i = IPneighborhood(2,n,ip,el)
|
||||
neighbor_me = material_entry_phase(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
|
||||
neighbor_phase = material_ID_phase(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
|
||||
neighbors: do n = 1,nCellNeighbors
|
||||
el_nbr = geom(ph)%IPneighborhood(1,n,en)
|
||||
ip_nbr = geom(ph)%IPneighborhood(2,n,en)
|
||||
ce_nbr = (el_nbr-1)*discretization_nIPs + ip_nbr
|
||||
en_nbr = material_entry_phase(1,ce_nbr)
|
||||
ph_nbr = material_ID_phase(1,ce_nbr)
|
||||
|
||||
if (neighbor_e <= 0 .or. neighbor_i <= 0) then
|
||||
!* FREE SURFACE
|
||||
if (ce_nbr <= 0) then ! free surface
|
||||
forall(s1 = 1:ns) my_compatibility(:,s1,s1,n) = sqrt(prm%chi_surface)
|
||||
elseif (neighbor_phase /= ph) then
|
||||
!* PHASE BOUNDARY
|
||||
if (plasticState(neighbor_phase)%nonlocal .and. plasticState(ph)%nonlocal) &
|
||||
elseif (ph_nbr /= ph) then ! phase boundary
|
||||
if (plasticState(ph_nbr)%nonlocal .and. plasticState(ph)%nonlocal) &
|
||||
forall(s1 = 1:ns) my_compatibility(:,s1,s1,n) = 0.0_pREAL
|
||||
elseif (prm%chi_GB >= 0.0_pREAL) then
|
||||
!* GRAIN BOUNDARY
|
||||
elseif (prm%chi_GB >= 0.0_pREAL) then ! grain boundary
|
||||
if (any(dNeq(phase_O_0(ph)%data(en)%asQuaternion(), &
|
||||
phase_O_0(neighbor_phase)%data(neighbor_me)%asQuaternion())) .and. &
|
||||
plasticState(neighbor_phase)%nonlocal) &
|
||||
phase_O_0(ph_nbr)%data(en_nbr)%asQuaternion())) .and. &
|
||||
plasticState(ph_nbr)%nonlocal) &
|
||||
forall(s1 = 1:ns) my_compatibility(:,s1,s1,n) = sqrt(prm%chi_GB)
|
||||
else
|
||||
!* GRAIN BOUNDARY ?
|
||||
|
@ -1397,7 +1337,7 @@ module subroutine plastic_nonlocal_updateCompatibility(orientation,ce)
|
|||
!* the number of compatible slip systems is minimized with the sum of the original compatibility values exceeding one.
|
||||
!* Finally the smallest compatibility value is decreased until the sum is exactly equal to one.
|
||||
!* All values below the threshold are set to zero.
|
||||
mis = orientation(ph)%data(en)%misorientation(orientation(neighbor_phase)%data(neighbor_me))
|
||||
mis = orientation(ph)%data(en)%misorientation(orientation(ph_nbr)%data(en_nbr))
|
||||
mySlipSystems: do s1 = 1,ns
|
||||
neighborSlipSystems: do s2 = 1,ns
|
||||
my_compatibility(1,s2,s1,n) = math_inner(prm%slip_normal(1:3,s1), &
|
||||
|
@ -1431,7 +1371,7 @@ module subroutine plastic_nonlocal_updateCompatibility(orientation,ce)
|
|||
|
||||
end do neighbors
|
||||
|
||||
dependentState(ph)%compatibility(:,:,:,:,material_entry_phase(1,(el-1)*discretization_nIPs + ip)) = my_compatibility
|
||||
dependentState(ph)%compatibility(:,:,:,:,en) = my_compatibility
|
||||
|
||||
end associate
|
||||
|
||||
|
@ -1543,8 +1483,8 @@ subroutine stateInit(ini,phase,Nentries)
|
|||
associate(stt => state(phase))
|
||||
|
||||
if (ini%random_rho_u > 0.0_pREAL) then ! randomly distribute dislocation segments on random slip system and of random type in the volume
|
||||
totalVolume = sum(geom(phase)%V_0)
|
||||
minimumIPVolume = minval(geom(phase)%V_0)
|
||||
totalVolume = sum(geom(phase)%v_0)
|
||||
minimumIPVolume = minval(geom(phase)%v_0)
|
||||
densityBinning = ini%random_rho_u_binning / minimumIpVolume ** (2.0_pREAL / 3.0_pREAL)
|
||||
|
||||
! fill random material points with dislocation segments until the desired overall density is reached
|
||||
|
@ -1553,8 +1493,8 @@ subroutine stateInit(ini,phase,Nentries)
|
|||
call random_number(rnd)
|
||||
e = nint(rnd(1)*real(Nentries,pREAL) + 0.5_pREAL)
|
||||
s = nint(rnd(2)*real(sum(ini%N_sl),pREAL)*4.0_pREAL + 0.5_pREAL)
|
||||
meanDensity = meanDensity + densityBinning * geom(phase)%V_0(e) / totalVolume
|
||||
stt%rhoSglMobile(s,e) = densityBinning
|
||||
meanDensity = meanDensity + densityBinning * geom(phase)%v_0(e) / totalVolume
|
||||
stt%rho_sgl_mob(s,e) = densityBinning
|
||||
end do
|
||||
else ! homogeneous distribution with noise
|
||||
do f = 1,size(ini%N_sl,1)
|
||||
|
@ -1684,7 +1624,7 @@ pure function getRho(ph,en) result(rho)
|
|||
rho(:,mob) = max(rho(:,mob),0.0_pREAL)
|
||||
rho(:,dip) = max(rho(:,dip),0.0_pREAL)
|
||||
|
||||
where(abs(rho) < max(prm%rho_min/geom(ph)%V_0(en)**(2.0_pREAL/3.0_pREAL),prm%rho_significant)) &
|
||||
where(abs(rho) < max(prm%rho_min/geom(ph)%v_0(en)**(2.0_pREAL/3.0_pREAL),prm%rho_significant)) &
|
||||
rho = 0.0_pREAL
|
||||
|
||||
end associate
|
||||
|
@ -1696,56 +1636,57 @@ end function getRho
|
|||
!> @brief returns copy of current dislocation densities from state
|
||||
!> @details raw values is rectified
|
||||
!--------------------------------------------------------------------------------------------------
|
||||
pure function getRho0(ph,en) result(rho0)
|
||||
pure function getRho0(ph,en) result(rho_0)
|
||||
|
||||
integer, intent(in) :: ph, en
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,10) :: rho0
|
||||
real(pREAL), dimension(param(ph)%sum_N_sl,10) :: rho_0
|
||||
|
||||
|
||||
associate(prm => param(ph))
|
||||
|
||||
rho0 = reshape(state0(ph)%rho(:,en),[prm%sum_N_sl,10])
|
||||
rho_0 = reshape(state0(ph)%rho(:,en),[prm%sum_N_sl,10])
|
||||
|
||||
! ensure positive densities (not for imm, they have a sign)
|
||||
rho0(:,mob) = max(rho0(:,mob),0.0_pREAL)
|
||||
rho0(:,dip) = max(rho0(:,dip),0.0_pREAL)
|
||||
rho_0(:,mob) = max(rho_0(:,mob),0.0_pREAL)
|
||||
rho_0(:,dip) = max(rho_0(:,dip),0.0_pREAL)
|
||||
|
||||
where (abs(rho0) < max(prm%rho_min/geom(ph)%V_0(en)**(2.0_pREAL/3.0_pREAL),prm%rho_significant)) &
|
||||
rho0 = 0.0_pREAL
|
||||
where (abs(rho_0) < max(prm%rho_min/geom(ph)%v_0(en)**(2.0_pREAL/3.0_pREAL),prm%rho_significant)) &
|
||||
rho_0 = 0.0_pREAL
|
||||
|
||||
end associate
|
||||
|
||||
end function getRho0
|
||||
|
||||
|
||||
!--------------------------------------------------------------------------------------------------
|
||||
!--------------------------------------------------------------------------------------------------
|
||||
subroutine storeGeometry(ph)
|
||||
|
||||
integer, intent(in) :: ph
|
||||
|
||||
integer :: ce, co, nCell
|
||||
real(pREAL), dimension(:), allocatable :: V
|
||||
integer :: ce, nCell
|
||||
real(pREAL), dimension(:), allocatable :: v_0
|
||||
real(pREAL), dimension(:,:), allocatable :: a_0, x_0
|
||||
real(pREAL), dimension(:,:,:), allocatable :: n_0
|
||||
integer, dimension(:,:,:), allocatable :: neighborhood
|
||||
real(pREAL), dimension(:,:), allocatable :: area, coords
|
||||
real(pREAL), dimension(:,:,:), allocatable :: areaNormal
|
||||
|
||||
nCell = product(shape(IPvolume))
|
||||
|
||||
V = reshape(IPvolume,[nCell])
|
||||
neighborhood = reshape(IPneighborhood,[3,nIPneighbors,nCell])
|
||||
area = reshape(IParea,[nIPneighbors,nCell])
|
||||
areaNormal = reshape(IPareaNormal,[3,nIPneighbors,nCell])
|
||||
coords = reshape(discretization_IPcoords,[3,nCell])
|
||||
nCell = product(shape(IPVolume0))
|
||||
|
||||
v_0 = reshape(IPVolume0,[nCell])
|
||||
a_0 = reshape(IPArea0,[nCellNeighbors,nCell])
|
||||
x_0 = reshape(discretization_IPcoords,[3,nCell])
|
||||
n_0 = reshape(IPAreaNormal0,[3,nCellNeighbors,nCell])
|
||||
neighborhood = reshape(IPneighborhood,[3,nCellNeighbors,nCell])
|
||||
|
||||
do ce = 1, size(material_entry_homogenization,1)
|
||||
do co = 1, homogenization_maxNconstituents
|
||||
if (material_ID_phase(co,ce) == ph) then
|
||||
geom(ph)%V_0(material_entry_phase(co,ce)) = V(ce)
|
||||
geom(ph)%IPneighborhood(:,:,material_entry_phase(co,ce)) = neighborhood(:,:,ce)
|
||||
geom(ph)%IParea(:,material_entry_phase(co,ce)) = area(:,ce)
|
||||
geom(ph)%IPareaNormal(:,:,material_entry_phase(co,ce)) = areaNormal(:,:,ce)
|
||||
geom(ph)%IPcoordinates(:,material_entry_phase(co,ce)) = coords(:,ce)
|
||||
end if
|
||||
end do
|
||||
if (material_ID_phase(1,ce) == ph) then
|
||||
geom(ph)%v_0(material_entry_phase(1,ce)) = v_0(ce)
|
||||
geom(ph)%a_0(:,material_entry_phase(1,ce)) = a_0(:,ce)
|
||||
geom(ph)%x_0(:,material_entry_phase(1,ce)) = x_0(:,ce)
|
||||
geom(ph)%n_0(:,:,material_entry_phase(1,ce)) = n_0(:,:,ce)
|
||||
geom(ph)%IPneighborhood(:,:,material_entry_phase(1,ce)) = neighborhood(:,:,ce)
|
||||
end if
|
||||
end do
|
||||
|
||||
end subroutine storeGeometry
|
||||
|
|
Loading…
Reference in New Issue