consistent naming with Python module

2023-07-15 20:28:57 +02:00 · 2023-07-15 20:28:57 +02:00 · e1630e4057
parent b578859ec9
commit e1630e4057
18 changed files with 227 additions and 227 deletions
--- a/src/CMakeLists.txt
+++ b/src/CMakeLists.txt
@ -1,7 +1,7 @@
 # special flags for some files
 if(CMAKE_Fortran_COMPILER_ID STREQUAL "GNU")
    # long lines for interaction matrix
-    set_source_files_properties("lattice.f90" PROPERTIES COMPILE_FLAGS "-ffree-line-length-240")
+    set_source_files_properties("crystal.f90" PROPERTIES COMPILE_FLAGS "-ffree-line-length-240")
    set_source_files_properties("parallelization.f90" PROPERTIES COMPILE_FLAGS "-ffree-line-length-none")
 endif()
--- a/src/IO.f90
+++ b/src/IO.f90
@ -476,7 +476,7 @@ subroutine IO_error(error_ID,ext_msg,label1,ID1,label2,ID2)
    case (131)
      msg = 'hex lattice structure with invalid c/a ratio'
    case (132)
-      msg = 'trans_lattice_structure not possible'
+      msg = 'invalid parameters for transformation'
    case (134)
      msg = 'negative lattice parameter'
    case (135)
--- a/src/Marc/DAMASK_Marc.f90
+++ b/src/Marc/DAMASK_Marc.f90
@ -155,7 +155,7 @@ end module DAMASK_interface
 #include "../rotations.f90"
 #include "../polynomials.f90"
 #include "../tables.f90"
-#include "../lattice.f90"
+#include "../crystal.f90"
 #include "element.f90"
 #include "../geometry_plastic_nonlocal.f90"
 #include "../discretization.f90"
--- a/src/Marc/materialpoint_Marc.f90
+++ b/src/Marc/materialpoint_Marc.f90
@ -16,7 +16,7 @@ module materialpoint_Marc
  use rotations
  use polynomials
  use tables
-  use lattice
+  use crystal
  use material
  use phase
  use homogenization
@ -75,7 +75,7 @@ subroutine materialpoint_initAll()
  call rotations_init()
  call polynomials_init()
  call tables_init()
-  call lattice_init()
+  call crystal_init()
  call discretization_Marc_init()
  call material_init(.false.)
  call phase_init()
--- a/src/crystal.f90
+++ b/src/crystal.f90
@ -3,10 +3,10 @@
 !> @author Philip Eisenlohr, Max-Planck-Institut für Eisenforschung GmbH
 !> @author Pratheek Shanthraj, Max-Planck-Institut für Eisenforschung GmbH
 !> @author Martin Diehl, Max-Planck-Institut für Eisenforschung GmbH
-!> @brief  contains lattice definitions including Schmid matrices for slip, twin, trans,
+!> @brief  Contains crystal definitions including Schmid matrices for slip, twin, trans,
-!          and cleavage as well as interaction among the various systems
+!          and cleavage as well as interaction among the various systems.
 !--------------------------------------------------------------------------------------------------
-module lattice
+module crystal
  use prec
  use misc
  use IO
@ -80,7 +80,7 @@ module lattice
      ],pREAL),shape(CF_SYSTEMTWIN))                                                                !< cF twin systems
  integer, dimension(2,CF_NTWIN), parameter, public :: &
-    lattice_CF_TWINNUCLEATIONSLIPPAIR = reshape( [&
+    crystal_CF_TWINNUCLEATIONSLIPPAIR = reshape( [&
      2,3, &
      1,3, &
      1,2, &
@ -93,7 +93,7 @@ module lattice
      11,12, &
      10,12, &
      10,11 &
-      ],shape(lattice_CF_TWINNUCLEATIONSLIPPAIR))
+      ],shape(crystal_CF_TWINNUCLEATIONSLIPPAIR))
  real(pREAL), dimension(3+3,CF_NCLEAVAGE), parameter :: &
    CF_SYSTEMCLEAVAGE = reshape(real([&
@ -367,60 +367,60 @@ module lattice
       ],pREAL),shape(TI_SYSTEMSLIP))                                                               !< tI slip systems for c/a = 0.5456 (Sn), sorted by Bieler 2009 (https://doi.org/10.1007/s11664-009-0909-x)
-  interface lattice_forestProjection_edge
+  interface crystal_forestProjection_edge
    module procedure slipProjection_transverse
-  end interface lattice_forestProjection_edge
+  end interface crystal_forestProjection_edge
-  interface lattice_forestProjection_screw
+  interface crystal_forestProjection_screw
    module procedure slipProjection_direction
-  end interface lattice_forestProjection_screw
+  end interface crystal_forestProjection_screw
  public :: &
-    lattice_init, &
+    crystal_init, &
-    lattice_isotropic_nu, &
+    crystal_isotropic_nu, &
-    lattice_isotropic_mu, &
+    crystal_isotropic_mu, &
-    lattice_symmetrize_33, &
+    crystal_symmetrize_33, &
-    lattice_symmetrize_C66, &
+    crystal_symmetrize_C66, &
-    lattice_SchmidMatrix_slip, &
+    crystal_SchmidMatrix_slip, &
-    lattice_SchmidMatrix_twin, &
+    crystal_SchmidMatrix_twin, &
-    lattice_SchmidMatrix_trans, &
+    crystal_SchmidMatrix_trans, &
-    lattice_SchmidMatrix_cleavage, &
+    crystal_SchmidMatrix_cleavage, &
-    lattice_nonSchmidMatrix, &
+    crystal_nonSchmidMatrix, &
-    lattice_interaction_SlipBySlip, &
+    crystal_interaction_SlipBySlip, &
-    lattice_interaction_TwinByTwin, &
+    crystal_interaction_TwinByTwin, &
-    lattice_interaction_TransByTrans, &
+    crystal_interaction_TransByTrans, &
-    lattice_interaction_SlipByTwin, &
+    crystal_interaction_SlipByTwin, &
-    lattice_interaction_SlipByTrans, &
+    crystal_interaction_SlipByTrans, &
-    lattice_interaction_TwinBySlip, &
+    crystal_interaction_TwinBySlip, &
-    lattice_characteristicShear_Twin, &
+    crystal_characteristicShear_Twin, &
-    lattice_C66_twin, &
+    crystal_C66_twin, &
-    lattice_C66_trans, &
+    crystal_C66_trans, &
-    lattice_forestProjection_edge, &
+    crystal_forestProjection_edge, &
-    lattice_forestProjection_screw, &
+    crystal_forestProjection_screw, &
-    lattice_slip_normal, &
+    crystal_slip_normal, &
-    lattice_slip_direction, &
+    crystal_slip_direction, &
-    lattice_slip_transverse, &
+    crystal_slip_transverse, &
-    lattice_labels_slip, &
+    crystal_labels_slip, &
-    lattice_labels_twin
+    crystal_labels_twin
 contains
 !--------------------------------------------------------------------------------------------------
 !> @brief Run self test.
 !--------------------------------------------------------------------------------------------------
-subroutine lattice_init()
+subroutine crystal_init()
-  print'(/,1x,a)', '<<<+-  lattice init  -+>>>'; flush(IO_STDOUT)
+  print'(/,1x,a)', '<<<+-  crystal init  -+>>>'; flush(IO_STDOUT)
  call selfTest()
-end subroutine lattice_init
+end subroutine crystal_init
 !--------------------------------------------------------------------------------------------------
 !> @brief Characteristic shear for twinning
 !--------------------------------------------------------------------------------------------------
-function lattice_characteristicShear_Twin(Ntwin,lattice,CoverA) result(characteristicShear)
+function crystal_characteristicShear_Twin(Ntwin,lattice,CoverA) result(characteristicShear)
  integer,     dimension(:),            intent(in) :: Ntwin                                         !< number of active twin systems per family
  character(len=*),                     intent(in) :: lattice                                       !< Bravais lattice (Pearson symbol)
@ -470,7 +470,7 @@ function lattice_characteristicShear_Twin(Ntwin,lattice,CoverA) result(character
          characteristicShear(a) = 0.5_pREAL*sqrt(2.0_pREAL)
        case('hP')
          if (cOverA < 1.0_pREAL .or. cOverA > 2.0_pREAL) &
-            call IO_error(131,ext_msg='lattice_characteristicShear_Twin')
+            call IO_error(131,ext_msg='crystal_characteristicShear_Twin')
          p = sum(HP_NTWINSYSTEM(1:f-1))+s
          select case(HP_SHEARTWIN(p))                                                              ! from Christian & Mahajan 1995 p.29
            case (1)                                                                                ! <-10.1>{10.2}
@ -483,24 +483,24 @@ function lattice_characteristicShear_Twin(Ntwin,lattice,CoverA) result(character
              characteristicShear(a) = 2.0_pREAL*(cOverA**2-2.0_pREAL)/3.0_pREAL/cOverA
          end select
        case default
-          call IO_error(137,ext_msg='lattice_characteristicShear_Twin: '//trim(lattice))
+          call IO_error(137,ext_msg='crystal_characteristicShear_Twin: '//trim(lattice))
      end select
    end do mySystems
  end do myFamilies
-end function lattice_characteristicShear_Twin
+end function crystal_characteristicShear_Twin
 !--------------------------------------------------------------------------------------------------
 !> @brief Rotated elasticity matrices for twinning in 6x6-matrix notation
 !--------------------------------------------------------------------------------------------------
-function lattice_C66_twin(Ntwin,C66,lattice,CoverA)
+function crystal_C66_twin(Ntwin,C66,lattice,CoverA)
  integer,     dimension(:),            intent(in) :: Ntwin                                         !< number of active twin systems per family
  character(len=*),                     intent(in) :: lattice                                       !< Bravais lattice (Pearson symbol)
  real(pREAL), dimension(6,6),          intent(in) :: C66                                           !< unrotated parent stiffness matrix
  real(pREAL),                          intent(in) :: cOverA                                        !< c/a ratio
-  real(pREAL), dimension(6,6,sum(Ntwin))           :: lattice_C66_twin
+  real(pREAL), dimension(6,6,sum(Ntwin))           :: crystal_C66_twin
  real(pREAL), dimension(3,3,sum(Ntwin)):: coordinateSystem
  type(tRotation)                       :: R
@ -518,28 +518,28 @@ function lattice_C66_twin(Ntwin,C66,lattice,CoverA)
      coordinateSystem = buildCoordinateSystem(Ntwin,HP_NSLIPSYSTEM,HP_SYSTEMTWIN,&
                                               lattice,cOverA)
    case default
-      call IO_error(137,ext_msg='lattice_C66_twin: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_C66_twin: '//trim(lattice))
  end select
  do i = 1, sum(Ntwin)
    call R%fromAxisAngle([coordinateSystem(1:3,2,i),PI],P=1)                                        ! ToDo: Why always 180 deg?
-    lattice_C66_twin(1:6,1:6,i) = R%rotStiffness(C66)
+    crystal_C66_twin(1:6,1:6,i) = R%rotStiffness(C66)
  end do
-end function lattice_C66_twin
+end function crystal_C66_twin
 !--------------------------------------------------------------------------------------------------
 !> @brief Rotated elasticity matrices for transformation in 6x6-matrix notation
 !--------------------------------------------------------------------------------------------------
-function lattice_C66_trans(Ntrans,C_parent66,lattice_target, &
+function crystal_C66_trans(Ntrans,C_parent66,crystal_target, &
                           cOverA_trans,a_cF,a_cI)
  integer,     dimension(:),             intent(in) :: Ntrans                                       !< number of active twin systems per family
-  character(len=*),                      intent(in) :: lattice_target                               !< Bravais lattice (Pearson symbol)
+  character(len=*),                      intent(in) :: crystal_target                               !< Bravais lattice (Pearson symbol)
  real(pREAL), dimension(6,6),           intent(in) :: C_parent66
  real(pREAL),                 optional, intent(in) :: cOverA_trans, a_cF, a_cI
-  real(pREAL), dimension(6,6,sum(Ntrans))           :: lattice_C66_trans
+  real(pREAL), dimension(6,6,sum(Ntrans))           :: crystal_C66_trans
  real(pREAL), dimension(6,6)             :: C_bar66, C_target_unrotated66
  real(pREAL), dimension(3,3,sum(Ntrans)) :: Q,S
@ -548,11 +548,11 @@ function lattice_C66_trans(Ntrans,C_parent66,lattice_target, &
 !--------------------------------------------------------------------------------------------------
 ! elasticity matrix of the target phase in cube orientation
-  if (lattice_target == 'hP' .and. present(cOverA_trans)) then
+  if (crystal_target == 'hP' .and. present(cOverA_trans)) then
    ! https://doi.org/10.1063/1.1663858 eq. (16), eq. (18), eq. (19)
    ! https://doi.org/10.1016/j.actamat.2016.07.032 eq. (47), eq. (48)
    if (cOverA_trans < 1.0_pREAL .or. cOverA_trans > 2.0_pREAL) &
-      call IO_error(131,ext_msg='lattice_C66_trans: '//trim(lattice_target))
+      call IO_error(131,ext_msg='crystal_C66_trans: '//trim(crystal_target))
    C_bar66(1,1) = (C_parent66(1,1) + C_parent66(1,2) + 2.0_pREAL*C_parent66(4,4))/2.0_pREAL
    C_bar66(1,2) = (C_parent66(1,1) + 5.0_pREAL*C_parent66(1,2) - 2.0_pREAL*C_parent66(4,4))/6.0_pREAL
    C_bar66(3,3) = (C_parent66(1,1) + 2.0_pREAL*C_parent66(1,2) + 4.0_pREAL*C_parent66(4,4))/3.0_pREAL
@ -566,13 +566,13 @@ function lattice_C66_trans(Ntrans,C_parent66,lattice_target, &
    C_target_unrotated66(1,3) = C_bar66(1,3)
    C_target_unrotated66(3,3) = C_bar66(3,3)
    C_target_unrotated66(4,4) = C_bar66(4,4) - C_bar66(1,4)**2/(0.5_pREAL*(C_bar66(1,1) - C_bar66(1,2)))
-    C_target_unrotated66 = lattice_symmetrize_C66(C_target_unrotated66,'hP')
+    C_target_unrotated66 = crystal_symmetrize_C66(C_target_unrotated66,'hP')
-  elseif (lattice_target  == 'cI' .and. present(a_cF) .and. present(a_cI)) then
+  elseif (crystal_target  == 'cI' .and. present(a_cF) .and. present(a_cI)) then
    if (a_cI <= 0.0_pREAL .or. a_cF <= 0.0_pREAL) &
-      call IO_error(134,ext_msg='lattice_C66_trans: '//trim(lattice_target))
+      call IO_error(134,ext_msg='crystal_C66_trans: '//trim(crystal_target))
    C_target_unrotated66 = C_parent66
  else
-    call IO_error(137,ext_msg='lattice_C66_trans : '//trim(lattice_target))
+    call IO_error(137,ext_msg='crystal_C66_trans : '//trim(crystal_target))
  end if
  do i = 1,6
@ -584,10 +584,10 @@ function lattice_C66_trans(Ntrans,C_parent66,lattice_target, &
  do i = 1,sum(Ntrans)
    call R%fromMatrix(Q(1:3,1:3,i))
-    lattice_C66_trans(1:6,1:6,i) = R%rotStiffness(C_target_unrotated66)
+    crystal_C66_trans(1:6,1:6,i) = R%rotStiffness(C_target_unrotated66)
  end do
- end function lattice_C66_trans
+ end function crystal_C66_trans
 !--------------------------------------------------------------------------------------------------
@ -595,7 +595,7 @@ function lattice_C66_trans(Ntrans,C_parent66,lattice_target, &
 ! https://doi.org/10.1016/j.actamat.2012.03.053, eq. (17)
 ! https://doi.org/10.1016/j.actamat.2008.07.037, table 1
 !--------------------------------------------------------------------------------------------------
-function lattice_nonSchmidMatrix(Nslip,nonSchmidCoefficients,sense) result(nonSchmidMatrix)
+function crystal_nonSchmidMatrix(Nslip,nonSchmidCoefficients,sense) result(nonSchmidMatrix)
  integer,     dimension(:),                intent(in) :: Nslip                                     !< number of active slip systems per family
  real(pREAL), dimension(:),                intent(in) :: nonSchmidCoefficients                     !< non-Schmid coefficients for projections
@ -608,11 +608,11 @@ function lattice_nonSchmidMatrix(Nslip,nonSchmidCoefficients,sense) result(nonSc
  integer                                              :: i
-  if (abs(sense) /= 1) error stop 'Sense in lattice_nonSchmidMatrix'
+  if (abs(sense) /= 1) error stop 'Sense in crystal_nonSchmidMatrix'
  coordinateSystem  = buildCoordinateSystem(Nslip,CI_NSLIPSYSTEM,CI_SYSTEMSLIP,'cI',0.0_pREAL)
  coordinateSystem(1:3,1,1:sum(Nslip)) = coordinateSystem(1:3,1,1:sum(Nslip))*real(sense,pREAL)     ! convert unidirectional coordinate system
-  nonSchmidMatrix = lattice_SchmidMatrix_slip(Nslip,'cI',0.0_pREAL)                                 ! Schmid contribution
+  nonSchmidMatrix = crystal_SchmidMatrix_slip(Nslip,'cI',0.0_pREAL)                                 ! Schmid contribution
  do i = 1,sum(Nslip)
    direction = coordinateSystem(1:3,1,i)
@ -635,7 +635,7 @@ function lattice_nonSchmidMatrix(Nslip,nonSchmidCoefficients,sense) result(nonSc
      + nonSchmidCoefficients(6) * math_outer(direction, direction)
  end do
-end function lattice_nonSchmidMatrix
+end function crystal_nonSchmidMatrix
 !--------------------------------------------------------------------------------------------------
@ -644,7 +644,7 @@ end function lattice_nonSchmidMatrix
 !> @details https://doi.org/10.1016/j.actamat.2016.12.040 (cF: Tab S4-1, cI: Tab S5-1)
 !> @details https://doi.org/10.1016/j.ijplas.2014.06.010 (hP: Tab 3b)
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_SlipBySlip(Nslip,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_SlipBySlip(Nslip,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                   intent(in) :: Nslip                              !< number of active slip systems per family
  real(pREAL),     dimension(:),                   intent(in) :: interactionValues                  !< values for slip-slip interaction
@ -950,19 +950,19 @@ function lattice_interaction_SlipBySlip(Nslip,interactionValues,lattice) result(
      interactionTypes = TI_INTERACTIONSLIPSLIP
      NslipMax         = TI_NSLIPSYSTEM
    case default
-      call IO_error(137,ext_msg='lattice_interaction_SlipBySlip: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_interaction_SlipBySlip: '//trim(lattice))
  end select
  interactionMatrix = buildInteraction(Nslip,Nslip,NslipMax,NslipMax,interactionValues,interactionTypes)
-end function lattice_interaction_SlipBySlip
+end function crystal_interaction_SlipBySlip
 !--------------------------------------------------------------------------------------------------
 !> @brief Twin-twin interaction matrix
 !> details only active twin systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_TwinByTwin(Ntwin,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_TwinByTwin(Ntwin,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                   intent(in) :: Ntwin                              !< number of active twin systems per family
  real(pREAL),     dimension(:),                   intent(in) :: interactionValues                  !< values for twin-twin interaction
@ -1049,19 +1049,19 @@ function lattice_interaction_TwinByTwin(Ntwin,interactionValues,lattice) result(
      interactionTypes = HP_INTERACTIONTWINTWIN
      NtwinMax         = HP_NTWINSYSTEM
    case default
-      call IO_error(137,ext_msg='lattice_interaction_TwinByTwin: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_interaction_TwinByTwin: '//trim(lattice))
  end select
  interactionMatrix = buildInteraction(Ntwin,Ntwin,NtwinMax,NtwinMax,interactionValues,interactionTypes)
-end function lattice_interaction_TwinByTwin
+end function crystal_interaction_TwinByTwin
 !--------------------------------------------------------------------------------------------------
 !> @brief Trans-trans interaction matrix
 !> details only active trans systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_TransByTrans(Ntrans,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_TransByTrans(Ntrans,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                     intent(in) :: Ntrans                           !< number of active trans systems per family
  real(pREAL),     dimension(:),                     intent(in) :: interactionValues                !< values for trans-trans interaction
@ -1091,19 +1091,19 @@ function lattice_interaction_TransByTrans(Ntrans,interactionValues,lattice) resu
    interactionTypes = CF_INTERACTIONTRANSTRANS
    NtransMax        = CF_NTRANSSYSTEM
  else
-    call IO_error(137,ext_msg='lattice_interaction_TransByTrans: '//trim(lattice))
+    call IO_error(137,ext_msg='crystal_interaction_TransByTrans: '//trim(lattice))
  end if
  interactionMatrix = buildInteraction(Ntrans,Ntrans,NtransMax,NtransMax,interactionValues,interactionTypes)
-end function lattice_interaction_TransByTrans
+end function crystal_interaction_TransByTrans
 !--------------------------------------------------------------------------------------------------
 !> @brief Slip-twin interaction matrix
 !> details only active slip and twin systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_SlipByTwin(Nslip,Ntwin,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_SlipByTwin(Nslip,Ntwin,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                   intent(in) :: Nslip, &                           !< number of active slip systems per family
                                                                 Ntwin                              !< number of active twin systems per family
@ -1251,19 +1251,19 @@ function lattice_interaction_SlipByTwin(Nslip,Ntwin,interactionValues,lattice) r
      NslipMax         = HP_NSLIPSYSTEM
      NtwinMax         = HP_NTWINSYSTEM
    case default
-      call IO_error(137,ext_msg='lattice_interaction_SlipByTwin: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_interaction_SlipByTwin: '//trim(lattice))
  end select
  interactionMatrix = buildInteraction(Nslip,Ntwin,NslipMax,NtwinMax,interactionValues,interactionTypes)
-end function lattice_interaction_SlipByTwin
+end function crystal_interaction_SlipByTwin
 !--------------------------------------------------------------------------------------------------
 !> @brief Slip-trans interaction matrix
 !> details only active slip and trans systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_SlipByTrans(Nslip,Ntrans,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_SlipByTrans(Nslip,Ntrans,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                    intent(in) :: Nslip, &                          !< number of active slip systems per family
                                                                  Ntrans                            !< number of active trans systems per family
@ -1304,19 +1304,19 @@ function lattice_interaction_SlipByTrans(Nslip,Ntrans,interactionValues,lattice)
      NslipMax         = CF_NSLIPSYSTEM
      NtransMax        = CF_NTRANSSYSTEM
    case default
-      call IO_error(137,ext_msg='lattice_interaction_SlipByTrans: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_interaction_SlipByTrans: '//trim(lattice))
  end select
  interactionMatrix = buildInteraction(Nslip,Ntrans,NslipMax,NtransMax,interactionValues,interactionTypes)
- end function lattice_interaction_SlipByTrans
+ end function crystal_interaction_SlipByTrans
 !--------------------------------------------------------------------------------------------------
 !> @brief Twin-slip interaction matrix
 !> details only active twin and slip systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_interaction_TwinBySlip(Ntwin,Nslip,interactionValues,lattice) result(interactionMatrix)
+function crystal_interaction_TwinBySlip(Ntwin,Nslip,interactionValues,lattice) result(interactionMatrix)
  integer,         dimension(:),                   intent(in) :: Ntwin, &                           !< number of active twin systems per family
                                                                 Nslip                              !< number of active slip systems per family
@ -1380,19 +1380,19 @@ function lattice_interaction_TwinBySlip(Ntwin,Nslip,interactionValues,lattice) r
      NtwinMax         = HP_NTWINSYSTEM
      NslipMax         = HP_NSLIPSYSTEM
    case default
-      call IO_error(137,ext_msg='lattice_interaction_TwinBySlip: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_interaction_TwinBySlip: '//trim(lattice))
  end select
  interactionMatrix = buildInteraction(Ntwin,Nslip,NtwinMax,NslipMax,interactionValues,interactionTypes)
-end function lattice_interaction_TwinBySlip
+end function crystal_interaction_TwinBySlip
 !--------------------------------------------------------------------------------------------------
 !> @brief Schmid matrix for slip
 !> details only active slip systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_SchmidMatrix_slip(Nslip,lattice,cOverA) result(SchmidMatrix)
+function crystal_SchmidMatrix_slip(Nslip,lattice,cOverA) result(SchmidMatrix)
  integer,         dimension(:),            intent(in) :: Nslip                                     !< number of active slip systems per family
  character(len=*),                         intent(in) :: lattice                                   !< Bravais lattice (Pearson symbol)
@ -1419,7 +1419,7 @@ function lattice_SchmidMatrix_slip(Nslip,lattice,cOverA) result(SchmidMatrix)
      slipSystems = TI_SYSTEMSLIP
    case default
      allocate(NslipMax(0))
-      call IO_error(137,ext_msg='lattice_SchmidMatrix_slip: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_SchmidMatrix_slip: '//trim(lattice))
  end select
  if (any(NslipMax(1:size(Nslip)) - Nslip < 0)) &
@ -1435,14 +1435,14 @@ function lattice_SchmidMatrix_slip(Nslip,lattice,cOverA) result(SchmidMatrix)
      error stop 'dilatational Schmid matrix for slip'
  end do
-end function lattice_SchmidMatrix_slip
+end function crystal_SchmidMatrix_slip
 !--------------------------------------------------------------------------------------------------
 !> @brief Schmid matrix for twinning
 !> details only active twin systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_SchmidMatrix_twin(Ntwin,lattice,cOverA) result(SchmidMatrix)
+function crystal_SchmidMatrix_twin(Ntwin,lattice,cOverA) result(SchmidMatrix)
  integer,         dimension(:),            intent(in) :: Ntwin                                     !< number of active twin systems per family
  character(len=*),                         intent(in) :: lattice                                   !< Bravais lattice (Pearson symbol)
@ -1466,7 +1466,7 @@ function lattice_SchmidMatrix_twin(Ntwin,lattice,cOverA) result(SchmidMatrix)
      twinSystems = HP_SYSTEMTWIN
    case default
      allocate(NtwinMax(0))
-      call IO_error(137,ext_msg='lattice_SchmidMatrix_twin: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_SchmidMatrix_twin: '//trim(lattice))
  end select
  if (any(NtwinMax(1:size(Ntwin)) - Ntwin < 0)) &
@ -1482,43 +1482,43 @@ function lattice_SchmidMatrix_twin(Ntwin,lattice,cOverA) result(SchmidMatrix)
      error stop 'dilatational Schmid matrix for twin'
  end do
-end function lattice_SchmidMatrix_twin
+end function crystal_SchmidMatrix_twin
 !--------------------------------------------------------------------------------------------------
 !> @brief Schmid matrix for transformation
 !> details only active twin systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_SchmidMatrix_trans(Ntrans,lattice_target,cOverA,a_cF,a_cI) result(SchmidMatrix)
+function crystal_SchmidMatrix_trans(Ntrans,crystal_target,cOverA,a_cF,a_cI) result(SchmidMatrix)
  integer,         dimension(:),             intent(in) :: Ntrans                                   !< number of active twin systems per family
-  character(len=*),                          intent(in) :: lattice_target                           !< Bravais lattice (Pearson symbol)
+  character(len=*),                          intent(in) :: crystal_target                           !< Bravais lattice (Pearson symbol)
  real(pREAL),                     optional, intent(in) :: cOverA, a_cI, a_cF
  real(pREAL),     dimension(3,3,sum(Ntrans))           :: SchmidMatrix
  real(pREAL), dimension(3,3,sum(Ntrans)) :: devNull
-  if (lattice_target == 'hP' .and. present(cOverA)) then
+  if (crystal_target == 'hP' .and. present(cOverA)) then
    if (cOverA < 1.0_pREAL .or. cOverA > 2.0_pREAL) &
-    call IO_error(131,ext_msg='lattice_SchmidMatrix_trans: '//trim(lattice_target))
+    call IO_error(131,ext_msg='crystal_SchmidMatrix_trans: '//trim(crystal_target))
    call buildTransformationSystem(devNull,SchmidMatrix,Ntrans,cOverA=cOverA)
-  else if (lattice_target == 'cI' .and. present(a_cF) .and. present(a_cI)) then
+  else if (crystal_target == 'cI' .and. present(a_cF) .and. present(a_cI)) then
    if (a_cI <= 0.0_pREAL .or. a_cF <= 0.0_pREAL) &
-    call IO_error(134,ext_msg='lattice_SchmidMatrix_trans: '//trim(lattice_target))
+    call IO_error(134,ext_msg='crystal_SchmidMatrix_trans: '//trim(crystal_target))
    call buildTransformationSystem(devNull,SchmidMatrix,Ntrans,a_cF=a_cF,a_cI=a_cI)
  else
-    call IO_error(131,ext_msg='lattice_SchmidMatrix_trans: '//trim(lattice_target))
+    call IO_error(131,ext_msg='crystal_SchmidMatrix_trans: '//trim(crystal_target))
  end if
-end function lattice_SchmidMatrix_trans
+end function crystal_SchmidMatrix_trans
 !--------------------------------------------------------------------------------------------------
 !> @brief Schmid matrix for cleavage
 !> details only active cleavage systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_SchmidMatrix_cleavage(Ncleavage,lattice,cOverA) result(SchmidMatrix)
+function crystal_SchmidMatrix_cleavage(Ncleavage,lattice,cOverA) result(SchmidMatrix)
  integer,         dimension(:),                  intent(in) :: Ncleavage                           !< number of active cleavage systems per family
  character(len=*),                               intent(in) :: lattice                             !< Bravais lattice (Pearson symbol)
@ -1539,7 +1539,7 @@ function lattice_SchmidMatrix_cleavage(Ncleavage,lattice,cOverA) result(SchmidMa
      cleavageSystems = CI_SYSTEMCLEAVAGE
    case default
      allocate(NcleavageMax(0))
-      call IO_error(137,ext_msg='lattice_SchmidMatrix_cleavage: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_SchmidMatrix_cleavage: '//trim(lattice))
  end select
  if (any(NcleavageMax(1:size(Ncleavage)) - Ncleavage < 0)) &
@ -1555,13 +1555,13 @@ function lattice_SchmidMatrix_cleavage(Ncleavage,lattice,cOverA) result(SchmidMa
    SchmidMatrix(1:3,1:3,3,i) = math_outer(coordinateSystem(1:3,2,i),coordinateSystem(1:3,2,i))
  end do
-end function lattice_SchmidMatrix_cleavage
+end function crystal_SchmidMatrix_cleavage
 !--------------------------------------------------------------------------------------------------
 !> @brief Slip direction of slip systems (|| b)
 !--------------------------------------------------------------------------------------------------
-function lattice_slip_direction(Nslip,lattice,cOverA) result(d)
+function crystal_slip_direction(Nslip,lattice,cOverA) result(d)
  integer,         dimension(:),           intent(in) :: Nslip                                      !< number of active slip systems per family
  character(len=*),                        intent(in) :: lattice                                    !< Bravais lattice (Pearson symbol)
@ -1573,13 +1573,13 @@ function lattice_slip_direction(Nslip,lattice,cOverA) result(d)
  coordinateSystem = coordinateSystem_slip(Nslip,lattice,cOverA)
  d = coordinateSystem(1:3,1,1:sum(Nslip))
-end function lattice_slip_direction
+end function crystal_slip_direction
 !--------------------------------------------------------------------------------------------------
 !> @brief Normal direction of slip systems (|| n)
 !--------------------------------------------------------------------------------------------------
-function lattice_slip_normal(Nslip,lattice,cOverA) result(n)
+function crystal_slip_normal(Nslip,lattice,cOverA) result(n)
  integer,         dimension(:),           intent(in) :: Nslip                                      !< number of active slip systems per family
  character(len=*),                        intent(in) :: lattice                                    !< Bravais lattice (Pearson symbol)
@ -1591,13 +1591,13 @@ function lattice_slip_normal(Nslip,lattice,cOverA) result(n)
  coordinateSystem = coordinateSystem_slip(Nslip,lattice,cOverA)
  n = coordinateSystem(1:3,2,1:sum(Nslip))
-end function lattice_slip_normal
+end function crystal_slip_normal
 !--------------------------------------------------------------------------------------------------
 !> @brief Transverse direction of slip systems (|| t = b x n)
 !--------------------------------------------------------------------------------------------------
-function lattice_slip_transverse(Nslip,lattice,cOverA) result(t)
+function crystal_slip_transverse(Nslip,lattice,cOverA) result(t)
  integer,         dimension(:),           intent(in) :: Nslip                                      !< number of active slip systems per family
  character(len=*),                        intent(in) :: lattice                                    !< Bravais lattice (Pearson symbol)
@ -1609,14 +1609,14 @@ function lattice_slip_transverse(Nslip,lattice,cOverA) result(t)
  coordinateSystem = coordinateSystem_slip(Nslip,lattice,cOverA)
  t = coordinateSystem(1:3,3,1:sum(Nslip))
-end function lattice_slip_transverse
+end function crystal_slip_transverse
 !--------------------------------------------------------------------------------------------------
 !> @brief Labels of slip systems
 !> details only active slip systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_labels_slip(Nslip,lattice) result(labels)
+function crystal_labels_slip(Nslip,lattice) result(labels)
  integer,         dimension(:),  intent(in)  :: Nslip                                              !< number of active slip systems per family
  character(len=*),               intent(in)  :: lattice                                            !< Bravais lattice (Pearson symbol)
@ -1640,7 +1640,7 @@ function lattice_labels_slip(Nslip,lattice) result(labels)
      NslipMax    = TI_NSLIPSYSTEM
      slipSystems = TI_SYSTEMSLIP
    case default
-      call IO_error(137,ext_msg='lattice_labels_slip: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_labels_slip: '//trim(lattice))
  end select
  if (any(NslipMax(1:size(Nslip)) - Nslip < 0)) &
@ -1650,13 +1650,13 @@ function lattice_labels_slip(Nslip,lattice) result(labels)
  labels = getLabels(Nslip,NslipMax,slipSystems)
-end function lattice_labels_slip
+end function crystal_labels_slip
 !--------------------------------------------------------------------------------------------------
 !> @brief Return 3x3 tensor with symmetry according to given Bravais lattice
 !--------------------------------------------------------------------------------------------------
-pure function lattice_symmetrize_33(T,lattice) result(T_sym)
+pure function crystal_symmetrize_33(T,lattice) result(T_sym)
  real(pREAL), dimension(3,3) :: T_sym
@ -1677,14 +1677,14 @@ pure function lattice_symmetrize_33(T,lattice) result(T_sym)
      T_sym(3,3) = T(3,3)
   end select
-end function lattice_symmetrize_33
+end function crystal_symmetrize_33
 !--------------------------------------------------------------------------------------------------
 !> @brief Return stiffness matrix in 6x6 notation with symmetry according to given Bravais lattice
 !> @details J. A. Rayne and B. S. Chandrasekhar Phys. Rev. 120, 1658 Erratum Phys. Rev. 122, 1962
 !--------------------------------------------------------------------------------------------------
-pure function lattice_symmetrize_C66(C66,lattice) result(C66_sym)
+pure function crystal_symmetrize_C66(C66,lattice) result(C66_sym)
  real(pREAL), dimension(6,6) :: C66_sym
@ -1723,14 +1723,14 @@ pure function lattice_symmetrize_C66(C66,lattice) result(C66_sym)
     end do
   end do
-end function lattice_symmetrize_C66
+end function crystal_symmetrize_C66
 !--------------------------------------------------------------------------------------------------
 !> @brief Labels for twin systems
 !> details only active twin systems are considered
 !--------------------------------------------------------------------------------------------------
-function lattice_labels_twin(Ntwin,lattice) result(labels)
+function crystal_labels_twin(Ntwin,lattice) result(labels)
  integer,         dimension(:),  intent(in)  :: Ntwin                                              !< number of active slip systems per family
  character(len=*),               intent(in)  :: lattice                                            !< Bravais lattice (Pearson symbol)
@ -1751,7 +1751,7 @@ function lattice_labels_twin(Ntwin,lattice) result(labels)
      NtwinMax    = HP_NTWINSYSTEM
      twinSystems = HP_SYSTEMTWIN
    case default
-      call IO_error(137,ext_msg='lattice_labels_twin: '//trim(lattice))
+      call IO_error(137,ext_msg='crystal_labels_twin: '//trim(lattice))
  end select
  if (any(NtwinMax(1:size(Ntwin)) - Ntwin < 0)) &
@ -1761,7 +1761,7 @@ function lattice_labels_twin(Ntwin,lattice) result(labels)
  labels = getLabels(Ntwin,NtwinMax,twinSystems)
-end function lattice_labels_twin
+end function crystal_labels_twin
 !--------------------------------------------------------------------------------------------------
@ -1778,8 +1778,8 @@ function slipProjection_transverse(Nslip,lattice,cOverA) result(projection)
  real(pREAL), dimension(3,sum(Nslip)) :: n, t
  integer                              :: i, j
-  n = lattice_slip_normal    (Nslip,lattice,cOverA)
+  n = crystal_slip_normal    (Nslip,lattice,cOverA)
-  t = lattice_slip_transverse(Nslip,lattice,cOverA)
+  t = crystal_slip_transverse(Nslip,lattice,cOverA)
  do i=1, sum(Nslip); do j=1, sum(Nslip)
    projection(i,j) = abs(math_inner(n(:,i),t(:,j)))
@ -1802,8 +1802,8 @@ function slipProjection_direction(Nslip,lattice,cOverA) result(projection)
  real(pREAL), dimension(3,sum(Nslip)) :: n, d
  integer                              :: i, j
-  n = lattice_slip_normal   (Nslip,lattice,cOverA)
+  n = crystal_slip_normal   (Nslip,lattice,cOverA)
-  d = lattice_slip_direction(Nslip,lattice,cOverA)
+  d = crystal_slip_direction(Nslip,lattice,cOverA)
  do i=1, sum(Nslip); do j=1, sum(Nslip)
    projection(i,j) = abs(math_inner(n(:,i),d(:,j)))
@ -2150,7 +2150,7 @@ end function getlabels
 !> @brief Equivalent Poisson's ratio (ν)
 !> @details https://doi.org/10.1143/JPSJ.20.635
 !--------------------------------------------------------------------------------------------------
-pure function lattice_isotropic_nu(C,assumption,lattice) result(nu)
+pure function crystal_isotropic_nu(C,assumption,lattice) result(nu)
  real(pREAL), dimension(6,6), intent(in) :: C                                                      !< Stiffness tensor (Voigt notation)
  character(len=*),            intent(in) :: assumption                                             !< Assumption (isostrain = 'Voigt', isostress = 'Reuss')
@ -2172,10 +2172,10 @@ pure function lattice_isotropic_nu(C,assumption,lattice) result(nu)
    error stop 'invalid assumption'
  end if
-  mu = lattice_isotropic_mu(C,assumption,lattice)
+  mu = crystal_isotropic_mu(C,assumption,lattice)
  nu = (1.5_pREAL*K-mu)/(3.0_pREAL*K+mu)
-end function lattice_isotropic_nu
+end function crystal_isotropic_nu
 !--------------------------------------------------------------------------------------------------
@ -2183,7 +2183,7 @@ end function lattice_isotropic_nu
 !> @details https://doi.org/10.1143/JPSJ.20.635
 !> @details Nonlinear Mechanics of Crystals 10.1007/978-94-007-0350-6, pp 563
 !--------------------------------------------------------------------------------------------------
-pure function lattice_isotropic_mu(C,assumption,lattice) result(mu)
+pure function crystal_isotropic_mu(C,assumption,lattice) result(mu)
  real(pREAL), dimension(6,6), intent(in) :: C                                                      !< Stiffness tensor (Voigt notation)
  character(len=*),            intent(in) :: assumption                                             !< Assumption (isostrain = 'Voigt', isostress = 'Reuss')
@ -2220,11 +2220,11 @@ pure function lattice_isotropic_mu(C,assumption,lattice) result(mu)
    error stop 'invalid assumption'
  end if
-end function lattice_isotropic_mu
+end function crystal_isotropic_mu
 !--------------------------------------------------------------------------------------------------
-!> @brief Check correctness of some lattice functions.
+!> @brief Check correctness of some crystal functions.
 !--------------------------------------------------------------------------------------------------
 subroutine selfTest
@ -2246,10 +2246,10 @@ subroutine selfTest
  do i = 1, 10
    call random_number(C)
-    C_cF = lattice_symmetrize_C66(C,'cI')
+    C_cF = crystal_symmetrize_C66(C,'cI')
-    C_cI = lattice_symmetrize_C66(C,'cF')
+    C_cI = crystal_symmetrize_C66(C,'cF')
-    C_hP = lattice_symmetrize_C66(C,'hP')
+    C_hP = crystal_symmetrize_C66(C,'hP')
-    C_tI = lattice_symmetrize_C66(C,'tI')
+    C_tI = crystal_symmetrize_C66(C,'tI')
    if (any(dNeq(C_cI,transpose(C_cF))))                   error stop 'SymmetryC66/cI-cF'
    if (any(dNeq(C_cF,transpose(C_cI))))                   error stop 'SymmetryC66/cF-cI'
@ -2269,10 +2269,10 @@ subroutine selfTest
    if (any(dNeq(C(4,4),[C_tI(4,4),C_tI(5,5)])))           error stop 'SymmetryC_44-55/tI'
    call random_number(T)
-    T_cF = lattice_symmetrize_33(T,'cI')
+    T_cF = crystal_symmetrize_33(T,'cI')
-    T_cI = lattice_symmetrize_33(T,'cF')
+    T_cI = crystal_symmetrize_33(T,'cF')
-    T_hP = lattice_symmetrize_33(T,'hP')
+    T_hP = crystal_symmetrize_33(T,'hP')
-    T_tI = lattice_symmetrize_33(T,'tI')
+    T_tI = crystal_symmetrize_33(T,'tI')
    if (any(dNeq0(T_cF) .and. math_I3<1.0_pREAL))          error stop 'Symmetry33/c'
    if (any(dNeq0(T_hP) .and. math_I3<1.0_pREAL))          error stop 'Symmetry33/hP'
@ -2291,48 +2291,48 @@ subroutine selfTest
  C(4,4) = 0.5_pREAL * (C(1,1) - C(1,2))
  C(6,6) = C(4,4)
-  C_cI = lattice_symmetrize_C66(C,'cI')
+  C_cI = crystal_symmetrize_C66(C,'cI')
-  if (dNeq(C_cI(4,4),lattice_isotropic_mu(C_cI,'isostrain','cI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/cI'
+  if (dNeq(C_cI(4,4),crystal_isotropic_mu(C_cI,'isostrain','cI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/cI'
-  if (dNeq(C_cI(4,4),lattice_isotropic_mu(C_cI,'isostress','cI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/cI'
+  if (dNeq(C_cI(4,4),crystal_isotropic_mu(C_cI,'isostress','cI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/cI'
  lambda = C_cI(1,2)
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_cI,'isostrain','cI')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_cI,'isostrain','cI')), &
-          lattice_isotropic_nu(C_cI,'isostrain','cI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/cI'
+          crystal_isotropic_nu(C_cI,'isostrain','cI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/cI'
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_cI,'isostress','cI')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_cI,'isostress','cI')), &
-          lattice_isotropic_nu(C_cI,'isostress','cI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/cI'
+          crystal_isotropic_nu(C_cI,'isostress','cI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/cI'
-  C_hP = lattice_symmetrize_C66(C,'hP')
+  C_hP = crystal_symmetrize_C66(C,'hP')
-  if (dNeq(C(4,4),lattice_isotropic_mu(C_hP,'isostrain','hP'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/hP'
+  if (dNeq(C(4,4),crystal_isotropic_mu(C_hP,'isostrain','hP'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/hP'
-  if (dNeq(C(4,4),lattice_isotropic_mu(C_hP,'isostress','hP'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/hP'
+  if (dNeq(C(4,4),crystal_isotropic_mu(C_hP,'isostress','hP'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/hP'
  lambda = C_hP(1,2)
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_hP,'isostrain','hP')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_hP,'isostrain','hP')), &
-          lattice_isotropic_nu(C_hP,'isostrain','hP'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/hP'
+          crystal_isotropic_nu(C_hP,'isostrain','hP'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/hP'
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_hP,'isostress','hP')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_hP,'isostress','hP')), &
-          lattice_isotropic_nu(C_hP,'isostress','hP'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/hP'
+          crystal_isotropic_nu(C_hP,'isostress','hP'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/hP'
-  C_tI = lattice_symmetrize_C66(C,'tI')
+  C_tI = crystal_symmetrize_C66(C,'tI')
-  if (dNeq(C(6,6),lattice_isotropic_mu(C_tI,'isostrain','tI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/tI'
+  if (dNeq(C(6,6),crystal_isotropic_mu(C_tI,'isostrain','tI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostrain/tI'
-  if (dNeq(C(6,6),lattice_isotropic_mu(C_tI,'isostress','tI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/tI'
+  if (dNeq(C(6,6),crystal_isotropic_mu(C_tI,'isostress','tI'),1.0e-12_pREAL)) error stop 'isotropic_mu/isostress/tI'
  lambda = C_tI(1,2)
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_tI,'isostrain','tI')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_tI,'isostrain','tI')), &
-          lattice_isotropic_nu(C_tI,'isostrain','tI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/tI'
+          crystal_isotropic_nu(C_tI,'isostrain','tI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostrain/tI'
-  if (dNeq(lambda*0.5_pREAL/(lambda+lattice_isotropic_mu(C_tI,'isostress','tI')), &
+  if (dNeq(lambda*0.5_pREAL/(lambda+crystal_isotropic_mu(C_tI,'isostress','tI')), &
-          lattice_isotropic_nu(C_tI,'isostress','tI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/tI'
+          crystal_isotropic_nu(C_tI,'isostress','tI'),1.0e-12_pREAL)) error stop 'isotropic_nu/isostress/tI'
  call random_number(C)
-  C = lattice_symmetrize_C66(C+math_eye(6),'cI')
+  C = crystal_symmetrize_C66(C+math_eye(6),'cI')
-  if (dNeq(lattice_isotropic_mu(C,'isostrain','cI'), lattice_isotropic_mu(C,'isostrain','hP'), 1.0e-12_pREAL)) &
+  if (dNeq(crystal_isotropic_mu(C,'isostrain','cI'), crystal_isotropic_mu(C,'isostrain','hP'), 1.0e-12_pREAL)) &
    error stop 'isotropic_mu/isostrain/cI-hP'
-  if (dNeq(lattice_isotropic_nu(C,'isostrain','cF'), lattice_isotropic_nu(C,'isostrain','cI'), 1.0e-12_pREAL)) &
+  if (dNeq(crystal_isotropic_nu(C,'isostrain','cF'), crystal_isotropic_nu(C,'isostrain','cI'), 1.0e-12_pREAL)) &
    error stop 'isotropic_nu/isostrain/cF-tI'
-  if (dNeq(lattice_isotropic_mu(C,'isostress','cI'), lattice_isotropic_mu(C,'isostress'), 1.0e-12_pREAL)) &
+  if (dNeq(crystal_isotropic_mu(C,'isostress','cI'), crystal_isotropic_mu(C,'isostress'), 1.0e-12_pREAL)) &
    error stop 'isotropic_mu/isostress/cI-hP'
-  if (dNeq(lattice_isotropic_nu(C,'isostress','cF'), lattice_isotropic_nu(C,'isostress'), 1.0e-12_pREAL)) &
+  if (dNeq(crystal_isotropic_nu(C,'isostress','cF'), crystal_isotropic_nu(C,'isostress'), 1.0e-12_pREAL)) &
    error stop 'isotropic_nu/isostress/cF-tI'
 end subroutine selfTest
-end module lattice
+end module crystal
--- a/src/homogenization.f90
+++ b/src/homogenization.f90
@ -16,7 +16,7 @@ module homogenization
  use HDF5
  use HDF5_utilities
  use result
-  use lattice
+  use crystal
  implicit none(type,external)
  private
--- a/src/homogenization_mechanical_RGC.f90
+++ b/src/homogenization_mechanical_RGC.f90
@ -8,7 +8,7 @@
 !--------------------------------------------------------------------------------------------------
 submodule(homogenization:mechanical) RGC
  use rotations
-  use lattice
+  use crystal
  type :: tParameters
    integer, dimension(:), allocatable :: &
@ -654,7 +654,7 @@ module function RGC_updateState(P,F,avgF,dt,dPdF,ce) result(doneAndHappy)
    C = phase_homogenizedC66(material_ID_phase(co,ce),material_entry_phase(co,ce))                  ! damage not included!
-    equivalentMu = lattice_isotropic_mu(C,'isostrain')
+    equivalentMu = crystal_isotropic_mu(C,'isostrain')
  end function equivalentMu
--- a/src/materialpoint.f90
+++ b/src/materialpoint.f90
@ -20,7 +20,7 @@ module materialpoint
  use rotations
  use polynomials
  use tables
-  use lattice
+  use crystal
  use material
  use phase
  use homogenization
@ -64,7 +64,7 @@ subroutine materialpoint_initAll()
  call rotations_init()
  call polynomials_init()
  call tables_init()
-  call lattice_init()
+  call crystal_init()
 #if   defined(MESH)
  call discretization_mesh_init(restart=CLI_restartInc>0)
 #elif defined(GRID)
--- a/src/phase.f90
+++ b/src/phase.f90
@ -14,7 +14,7 @@ module phase
  use config
  use material
  use result
-  use lattice
+  use crystal
  use discretization
  use parallelization
  use HDF5
@ -336,7 +336,7 @@ module phase
    config, &
    material, &
    result, &
-    lattice, &
+    crystal, &
    discretization, &
    HDF5_utilities
 #endif
--- a/src/phase_damage_anisobrittle.f90
+++ b/src/phase_damage_anisobrittle.f90
@ -77,7 +77,7 @@ module function anisobrittle_init() result(mySources)
        prm%s_crit  = src%get_as1dReal('s_crit',requiredSize=size(N_cl))
        prm%g_crit  = src%get_as1dReal('g_crit',requiredSize=size(N_cl))
-        prm%cleavage_systems = lattice_SchmidMatrix_cleavage(N_cl,phase_lattice(ph),phase_cOverA(ph))
+        prm%cleavage_systems = crystal_SchmidMatrix_cleavage(N_cl,phase_lattice(ph),phase_cOverA(ph))
        ! expand: family => system
        prm%s_crit = math_expand(prm%s_crit,N_cl)
--- a/src/phase_mechanical_eigen_thermalexpansion.f90
+++ b/src/phase_mechanical_eigen_thermalexpansion.f90
@ -92,7 +92,7 @@ module subroutine thermalexpansion_LiAndItsTangent(Li, dLi_dTstar, ph,me)
    Alpha = 0.0_pREAL
    Alpha(1,1) = prm%Alpha_11%at(T)
    if (any(phase_lattice(ph) == ['hP','tI'])) Alpha(3,3) = prm%Alpha_33%at(T)
-    Alpha = lattice_symmetrize_33(Alpha,phase_lattice(ph))
+    Alpha = crystal_symmetrize_33(Alpha,phase_lattice(ph))
    Li = dot_T * Alpha
  end associate
--- a/src/phase_mechanical_elastic.f90
+++ b/src/phase_mechanical_elastic.f90
@ -97,7 +97,7 @@ pure module function elastic_C66(ph,en) result(C66)
    if (phase_lattice(ph) == 'tI') C66(6,6) = prm%C_66%at(T)
-    C66 = lattice_symmetrize_C66(C66,phase_lattice(ph))
+    C66 = crystal_symmetrize_C66(C66,phase_lattice(ph))
  end associate
@ -119,7 +119,7 @@ pure module function elastic_mu(ph,en,isotropic_bound) result(mu)
  associate(prm => param(ph))
-    mu = lattice_isotropic_mu(elastic_C66(ph,en),isotropic_bound,phase_lattice(ph))
+    mu = crystal_isotropic_mu(elastic_C66(ph,en),isotropic_bound,phase_lattice(ph))
  end associate
@ -141,7 +141,7 @@ pure module function elastic_nu(ph,en,isotropic_bound) result(nu)
  associate(prm => param(ph))
-    nu = lattice_isotropic_nu(elastic_C66(ph,en),isotropic_bound,phase_lattice(ph))
+    nu = crystal_isotropic_nu(elastic_C66(ph,en),isotropic_bound,phase_lattice(ph))
  end associate
--- a/src/phase_mechanical_plastic_dislotungsten.f90
+++ b/src/phase_mechanical_plastic_dislotungsten.f90
@ -149,13 +149,13 @@ module function plastic_dislotungsten_init() result(myPlasticity)
    N_sl         = pl%get_as1dInt('N_sl',defaultVal=emptyIntArray)
    prm%sum_N_sl = sum(abs(N_sl))
    slipActive: if (prm%sum_N_sl > 0) then
-      prm%systems_sl = lattice_labels_slip(N_sl,phase_lattice(ph))
+      prm%systems_sl = crystal_labels_slip(N_sl,phase_lattice(ph))
-      prm%P_sl = lattice_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%P_sl = crystal_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
      if (phase_lattice(ph) == 'cI') then
        a = pl%get_as1dReal('a_nonSchmid',defaultVal = emptyRealArray)
-        prm%P_nS_pos = lattice_nonSchmidMatrix(N_sl,a,+1)
+        prm%P_nS_pos = crystal_nonSchmidMatrix(N_sl,a,+1)
-        prm%P_nS_neg = lattice_nonSchmidMatrix(N_sl,a,-1)
+        prm%P_nS_neg = crystal_nonSchmidMatrix(N_sl,a,-1)
      else
        prm%P_nS_pos = prm%P_sl
        prm%P_nS_neg = prm%P_sl
@ -184,13 +184,13 @@ module function plastic_dislotungsten_init() result(myPlasticity)
      prm%d_caron     = prm%b_sl *  pl%get_asReal('D_a')
      prm%f_at        = prm%b_sl**3*pl%get_asReal('f_at')
-      prm%h_sl_sl = lattice_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'), &
+      prm%h_sl_sl = crystal_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'), &
                                                   phase_lattice(ph))
      prm%forestProjection = spread(          f_edge,1,prm%sum_N_sl) &
-                           * lattice_forestProjection_edge (N_sl,phase_lattice(ph),phase_cOverA(ph)) &
+                           * crystal_forestProjection_edge (N_sl,phase_lattice(ph),phase_cOverA(ph)) &
                           + spread(1.0_pREAL-f_edge,1,prm%sum_N_sl) &
-                           * lattice_forestProjection_screw(N_sl,phase_lattice(ph),phase_cOverA(ph))
+                           * crystal_forestProjection_screw(N_sl,phase_lattice(ph),phase_cOverA(ph))
      ! sanity checks
      if (    prm%D_0          <  0.0_pREAL)  extmsg = trim(extmsg)//' D_0'
--- a/src/phase_mechanical_plastic_dislotwin.f90
+++ b/src/phase_mechanical_plastic_dislotwin.f90
@ -73,7 +73,7 @@ submodule(phase:plastic) dislotwin
    integer,                   allocatable, dimension(:,:) :: &
      fcc_twinNucleationSlipPair                                                                    ! ToDo: Better name? Is also used for trans
    character(len=:),          allocatable :: &
-      lattice_tr, &
+      crystal_tr, &
      isotropic_bound
    character(len=pSTRLEN),    allocatable, dimension(:) :: &
      output
@ -202,9 +202,9 @@ module function plastic_dislotwin_init() result(myPlasticity)
    N_sl         = pl%get_as1dInt('N_sl',defaultVal=emptyIntArray)
    prm%sum_N_sl = sum(abs(N_sl))
    slipActive: if (prm%sum_N_sl > 0) then
-      prm%systems_sl = lattice_labels_slip(N_sl,phase_lattice(ph))
+      prm%systems_sl = crystal_labels_slip(N_sl,phase_lattice(ph))
-      prm%P_sl       = lattice_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%P_sl       = crystal_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
-      prm%n0_sl      = lattice_slip_normal(N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%n0_sl      = crystal_slip_normal(N_sl,phase_lattice(ph),phase_cOverA(ph))
      prm%extendedDislocations = pl%get_asBool('extend_dislocations',defaultVal=.false.)
      prm%omitDipoles          = pl%get_asBool('omit_dipoles',       defaultVal=.false.)
@ -226,15 +226,15 @@ module function plastic_dislotwin_init() result(myPlasticity)
                                                 defaultVal=[(0.0_pREAL,i=1,size(N_sl))]),N_sl)
      prm%d_caron  = prm%b_sl *  pl%get_asReal('D_a')
-      prm%h_sl_sl = lattice_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'),phase_lattice(ph))
+      prm%h_sl_sl = crystal_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'),phase_lattice(ph))
      prm%forestProjection = spread(          f_edge,1,prm%sum_N_sl) &
-                           * lattice_forestProjection_edge (N_sl,phase_lattice(ph),phase_cOverA(ph)) &
+                           * crystal_forestProjection_edge (N_sl,phase_lattice(ph),phase_cOverA(ph)) &
                           + spread(1.0_pREAL-f_edge,1,prm%sum_N_sl) &
-                           * lattice_forestProjection_screw(N_sl,phase_lattice(ph),phase_cOverA(ph))
+                           * crystal_forestProjection_screw(N_sl,phase_lattice(ph),phase_cOverA(ph))
      prm%fccTwinTransNucleation = phase_lattice(ph) == 'cF' .and. N_sl(1) == 12
-      if (prm%fccTwinTransNucleation) prm%fcc_twinNucleationSlipPair = lattice_CF_TWINNUCLEATIONSLIPPAIR
+      if (prm%fccTwinTransNucleation) prm%fcc_twinNucleationSlipPair = crystal_CF_TWINNUCLEATIONSLIPPAIR
      ! multiplication factor according to crystal structure (nearest neighbors bcc vs fcc/hex)
      ! details: Argon & Moffat, Acta Metallurgica, Vol. 29, pg 293 to 299, 1981
@ -274,9 +274,9 @@ module function plastic_dislotwin_init() result(myPlasticity)
    prm%N_tw = pl%get_as1dInt('N_tw', defaultVal=emptyIntArray)
    prm%sum_N_tw = sum(abs(prm%N_tw))
    twinActive: if (prm%sum_N_tw > 0) then
-      prm%systems_tw    = lattice_labels_twin(prm%N_tw,phase_lattice(ph))
+      prm%systems_tw    = crystal_labels_twin(prm%N_tw,phase_lattice(ph))
-      prm%P_tw          = lattice_SchmidMatrix_twin(prm%N_tw,phase_lattice(ph),phase_cOverA(ph))
+      prm%P_tw          = crystal_SchmidMatrix_twin(prm%N_tw,phase_lattice(ph),phase_cOverA(ph))
-      prm%gamma_char_tw = lattice_characteristicShear_Twin(prm%N_tw,phase_lattice(ph),phase_cOverA(ph))
+      prm%gamma_char_tw = crystal_characteristicShear_Twin(prm%N_tw,phase_lattice(ph),phase_cOverA(ph))
      prm%L_tw             = pl%get_asReal('L_tw')
      prm%i_tw             = pl%get_asReal('i_tw')
@ -285,7 +285,7 @@ module function plastic_dislotwin_init() result(myPlasticity)
      prm%t_tw = math_expand(pl%get_as1dReal('t_tw', requiredSize=size(prm%N_tw)),prm%N_tw)
      prm%r    = math_expand(pl%get_as1dReal('p_tw', requiredSize=size(prm%N_tw)),prm%N_tw)
-      prm%h_tw_tw = lattice_interaction_TwinByTwin(prm%N_tw,pl%get_as1dReal('h_tw-tw'), &
+      prm%h_tw_tw = crystal_interaction_TwinByTwin(prm%N_tw,pl%get_as1dReal('h_tw-tw'), &
                                                   phase_lattice(ph))
      ! sanity checks
@ -309,7 +309,7 @@ module function plastic_dislotwin_init() result(myPlasticity)
    prm%N_tr = pl%get_as1dInt('N_tr', defaultVal=emptyIntArray)
    prm%sum_N_tr = sum(abs(prm%N_tr))
    transActive: if (prm%sum_N_tr > 0) then
-      prm%P_tr = lattice_SchmidMatrix_trans(prm%N_tr,'hP',prm%cOverA_hP)
+      prm%P_tr = crystal_SchmidMatrix_trans(prm%N_tr,'hP',prm%cOverA_hP)
      prm%Delta_G = polynomial(pl,'Delta_G','T')
      prm%i_tr            = pl%get_asReal('i_tr')
@ -324,7 +324,7 @@ module function plastic_dislotwin_init() result(myPlasticity)
      a_cF           = prm%b_tr(1)*sqrt(6.0_pREAL)                                                  ! b_tr is Shockley partial
      prm%h          = 5.0_pREAL * a_cF/sqrt(3.0_pREAL)
      prm%rho        = 4.0_pREAL/(sqrt(3.0_pREAL)*a_cF**2)/N_A
-      prm%h_tr_tr = lattice_interaction_TransByTrans(prm%N_tr,pl%get_as1dReal('h_tr-tr'),&
+      prm%h_tr_tr = crystal_interaction_TransByTrans(prm%N_tr,pl%get_as1dReal('h_tr-tr'),&
                                                     phase_lattice(ph))
@ -372,13 +372,13 @@ module function plastic_dislotwin_init() result(myPlasticity)
      prm%Gamma_sf = polynomial(pl,'Gamma_sf','T')
    slipAndTwinActive: if (prm%sum_N_sl * prm%sum_N_tw > 0) then
-      prm%h_sl_tw = lattice_interaction_SlipByTwin(N_sl,prm%N_tw,pl%get_as1dReal('h_sl-tw'), &
+      prm%h_sl_tw = crystal_interaction_SlipByTwin(N_sl,prm%N_tw,pl%get_as1dReal('h_sl-tw'), &
                                                   phase_lattice(ph))
      if (prm%fccTwinTransNucleation .and. size(prm%N_tw) /= 1) extmsg = trim(extmsg)//' N_tw: nucleation'
    end if slipAndTwinActive
    slipAndTransActive: if (prm%sum_N_sl * prm%sum_N_tr > 0) then
-      prm%h_sl_tr = lattice_interaction_SlipByTrans(N_sl,prm%N_tr,pl%get_as1dReal('h_sl-tr'), &
+      prm%h_sl_tr = crystal_interaction_SlipByTrans(N_sl,prm%N_tr,pl%get_as1dReal('h_sl-tr'), &
                                                    phase_lattice(ph))
      if (prm%fccTwinTransNucleation .and. size(prm%N_tr) /= 1) extmsg = trim(extmsg)//' N_tr: nucleation'
    end if slipAndTransActive
@ -480,7 +480,7 @@ module function plastic_dislotwin_homogenizedC(ph,en) result(homogenizedC)
    homogenizedC = f_matrix * C
    twinActive: if (prm%sum_N_tw > 0) then
-      C66_tw    = lattice_C66_twin(prm%N_tw,C,phase_lattice(ph),phase_cOverA(ph))
+      C66_tw    = crystal_C66_twin(prm%N_tw,C,phase_lattice(ph),phase_cOverA(ph))
      do i = 1, prm%sum_N_tw
        homogenizedC = homogenizedC &
                     + stt%f_tw(i,en)*C66_tw(1:6,1:6,i)
@ -488,7 +488,7 @@ module function plastic_dislotwin_homogenizedC(ph,en) result(homogenizedC)
     end if twinActive
    transActive: if (prm%sum_N_tr > 0) then
-      C66_tr    = lattice_C66_trans(prm%N_tr,C,'hP',prm%cOverA_hP)
+      C66_tr    = crystal_C66_trans(prm%N_tr,C,'hP',prm%cOverA_hP)
      do i = 1, prm%sum_N_tr
        homogenizedC = homogenizedC &
                     + stt%f_tr(i,en)*C66_tr(1:6,1:6,i)
--- a/src/phase_mechanical_plastic_kinehardening.f90
+++ b/src/phase_mechanical_plastic_kinehardening.f90
@ -139,14 +139,14 @@ module function plastic_kinehardening_init() result(myPlasticity)
    N_sl         = pl%get_as1dInt('N_sl',defaultVal=emptyIntArray)
    prm%sum_N_sl = sum(abs(N_sl))
    slipActive: if (prm%sum_N_sl > 0) then
-      prm%systems_sl = lattice_labels_slip(N_sl,phase_lattice(ph))
+      prm%systems_sl = crystal_labels_slip(N_sl,phase_lattice(ph))
-      prm%P = lattice_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%P = crystal_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
      if (phase_lattice(ph) == 'cI') then
        a = pl%get_as1dReal('a_nonSchmid',defaultVal=emptyRealArray)
        prm%nonSchmidActive = size(a) > 0
-        prm%P_nS_pos = lattice_nonSchmidMatrix(N_sl,a,+1)
+        prm%P_nS_pos = crystal_nonSchmidMatrix(N_sl,a,+1)
-        prm%P_nS_neg = lattice_nonSchmidMatrix(N_sl,a,-1)
+        prm%P_nS_neg = crystal_nonSchmidMatrix(N_sl,a,-1)
      else
        prm%P_nS_pos = prm%P
        prm%P_nS_neg = prm%P
@ -155,7 +155,7 @@ module function plastic_kinehardening_init() result(myPlasticity)
      prm%dot_gamma_0 = pl%get_asReal('dot_gamma_0')
      prm%n           = pl%get_asReal('n')
-      prm%h_sl_sl = lattice_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'), &
+      prm%h_sl_sl = crystal_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'), &
                                                   phase_lattice(ph))
      xi_0          = math_expand(pl%get_as1dReal('xi_0',      requiredSize=size(N_sl)),N_sl)
--- a/src/phase_mechanical_plastic_nonlocal.f90
+++ b/src/phase_mechanical_plastic_nonlocal.f90
@ -249,30 +249,30 @@ module function plastic_nonlocal_init() result(myPlasticity)
    ini%N_sl     = pl%get_as1dInt('N_sl',defaultVal=emptyIntArray)
    prm%sum_N_sl = sum(abs(ini%N_sl))
    slipActive: if (prm%sum_N_sl > 0) then
-      prm%systems_sl = lattice_labels_slip(ini%N_sl,phase_lattice(ph))
+      prm%systems_sl = crystal_labels_slip(ini%N_sl,phase_lattice(ph))
-      prm%P_sl = lattice_SchmidMatrix_slip(ini%N_sl,phase_lattice(ph), phase_cOverA(ph))
+      prm%P_sl = crystal_SchmidMatrix_slip(ini%N_sl,phase_lattice(ph), phase_cOverA(ph))
      if (phase_lattice(ph) == 'cI') then
        a = pl%get_as1dReal('a_nonSchmid',defaultVal = emptyRealArray)
        if (size(a) > 0) prm%nonSchmidActive = .true.
-        prm%P_nS_pos = lattice_nonSchmidMatrix(ini%N_sl,a,+1)
+        prm%P_nS_pos = crystal_nonSchmidMatrix(ini%N_sl,a,+1)
-        prm%P_nS_neg = lattice_nonSchmidMatrix(ini%N_sl,a,-1)
+        prm%P_nS_neg = crystal_nonSchmidMatrix(ini%N_sl,a,-1)
      else
        prm%P_nS_pos = prm%P_sl
        prm%P_nS_neg = prm%P_sl
      end if
-      prm%h_sl_sl = lattice_interaction_SlipBySlip(ini%N_sl,pl%get_as1dReal('h_sl-sl'), &
+      prm%h_sl_sl = crystal_interaction_SlipBySlip(ini%N_sl,pl%get_as1dReal('h_sl-sl'), &
                                                   phase_lattice(ph))
-      prm%forestProjection_edge  = lattice_forestProjection_edge (ini%N_sl,phase_lattice(ph),&
+      prm%forestProjection_edge  = crystal_forestProjection_edge (ini%N_sl,phase_lattice(ph),&
                                                                  phase_cOverA(ph))
-      prm%forestProjection_screw = lattice_forestProjection_screw(ini%N_sl,phase_lattice(ph),&
+      prm%forestProjection_screw = crystal_forestProjection_screw(ini%N_sl,phase_lattice(ph),&
                                                                  phase_cOverA(ph))
-      prm%slip_direction  = lattice_slip_direction (ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%slip_direction  = crystal_slip_direction (ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
-      prm%slip_transverse = lattice_slip_transverse(ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%slip_transverse = crystal_slip_transverse(ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
-      prm%slip_normal     = lattice_slip_normal    (ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%slip_normal     = crystal_slip_normal    (ini%N_sl,phase_lattice(ph),phase_cOverA(ph))
      ! collinear systems (only for octahedral slip systems in fcc)
      allocate(prm%colinearSystem(prm%sum_N_sl), source = -1)
--- a/src/phase_mechanical_plastic_phenopowerlaw.f90
+++ b/src/phase_mechanical_plastic_phenopowerlaw.f90
@ -149,21 +149,21 @@ module function plastic_phenopowerlaw_init() result(myPlasticity)
      prm%h_int     = math_expand(pl%get_as1dReal('h_int',     requiredSize=size(N_sl), &
                                                        defaultVal=[(0.0_pREAL,i=1,size(N_sl))]),N_sl)
-      prm%h_sl_sl = lattice_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'),phase_lattice(ph))
+      prm%h_sl_sl = crystal_interaction_SlipBySlip(N_sl,pl%get_as1dReal('h_sl-sl'),phase_lattice(ph))
-      prm%P_sl = lattice_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
+      prm%P_sl = crystal_SchmidMatrix_slip(N_sl,phase_lattice(ph),phase_cOverA(ph))
      if (phase_lattice(ph) == 'cI') then
        a = pl%get_as1dReal('a_nonSchmid',defaultVal=emptyRealArray)
        if (size(a) > 0) prm%nonSchmidActive = .true.
-        prm%P_nS_pos = lattice_nonSchmidMatrix(N_sl,a,+1)
+        prm%P_nS_pos = crystal_nonSchmidMatrix(N_sl,a,+1)
-        prm%P_nS_neg = lattice_nonSchmidMatrix(N_sl,a,-1)
+        prm%P_nS_neg = crystal_nonSchmidMatrix(N_sl,a,-1)
      else
        prm%P_nS_pos = prm%P_sl
        prm%P_nS_neg = prm%P_sl
      end if
-      prm%systems_sl = lattice_labels_slip(N_sl,phase_lattice(ph))
+      prm%systems_sl = crystal_labels_slip(N_sl,phase_lattice(ph))
      ! sanity checks
      if (    prm%dot_gamma_0_sl <= 0.0_pREAL)    extmsg = trim(extmsg)//' dot_gamma_0_sl'
@ -196,11 +196,11 @@ module function plastic_phenopowerlaw_init() result(myPlasticity)
      xi_0_tw = math_expand(pl%get_as1dReal('xi_0_tw',requiredSize=size(N_tw)),N_tw)
-      prm%gamma_char = lattice_characteristicShear_twin(N_tw,phase_lattice(ph),phase_cOverA(ph))
+      prm%gamma_char = crystal_characteristicShear_twin(N_tw,phase_lattice(ph),phase_cOverA(ph))
-      prm%h_tw_tw    = lattice_interaction_TwinByTwin(N_tw,pl%get_as1dReal('h_tw-tw'),phase_lattice(ph))
+      prm%h_tw_tw    = crystal_interaction_TwinByTwin(N_tw,pl%get_as1dReal('h_tw-tw'),phase_lattice(ph))
-      prm%P_tw       = lattice_SchmidMatrix_twin(N_tw,phase_lattice(ph),phase_cOverA(ph))
+      prm%P_tw       = crystal_SchmidMatrix_twin(N_tw,phase_lattice(ph),phase_cOverA(ph))
-      prm%systems_tw = lattice_labels_twin(N_tw,phase_lattice(ph))
+      prm%systems_tw = crystal_labels_twin(N_tw,phase_lattice(ph))
      ! sanity checks
      if (prm%dot_gamma_0_tw <= 0.0_pREAL)  extmsg = trim(extmsg)//' dot_gamma_0_tw'
@ -216,9 +216,9 @@ module function plastic_phenopowerlaw_init() result(myPlasticity)
 ! slip-twin related parameters
    slipAndTwinActive: if (prm%sum_N_sl > 0 .and. prm%sum_N_tw > 0) then
      prm%h_0_tw_sl  = pl%get_asReal('h_0_tw-sl')
-      prm%h_sl_tw    = lattice_interaction_SlipByTwin(N_sl,N_tw,pl%get_as1dReal('h_sl-tw'), &
+      prm%h_sl_tw    = crystal_interaction_SlipByTwin(N_sl,N_tw,pl%get_as1dReal('h_sl-tw'), &
                                                      phase_lattice(ph))
-      prm%h_tw_sl    = lattice_interaction_TwinBySlip(N_tw,N_sl,pl%get_as1dReal('h_tw-sl'), &
+      prm%h_tw_sl    = crystal_interaction_TwinBySlip(N_tw,N_sl,pl%get_as1dReal('h_tw-sl'), &
                                                      phase_lattice(ph))
    else slipAndTwinActive
      allocate(prm%h_sl_tw(prm%sum_N_sl,prm%sum_N_tw))                                              ! at least one dimension is 0
--- a/src/phase_thermal.f90
+++ b/src/phase_thermal.f90
@ -112,7 +112,7 @@ module subroutine thermal_init(phases)
      param(ph)%C_p = thermal%get_asReal('C_p')
      param(ph)%K(1,1) = thermal%get_asReal('K_11')
      if (any(phase_lattice(ph) == ['hP','tI'])) param(ph)%K(3,3) = thermal%get_asReal('K_33')
-      param(ph)%K = lattice_symmetrize_33(param(ph)%K,phase_lattice(ph))
+      param(ph)%K = crystal_symmetrize_33(param(ph)%K,phase_lattice(ph))
 #if defined(__GFORTRAN__)
      param(ph)%output = output_as1dStr(thermal)