mirror of https://gitlab.com/QEF/q-e.git
130 lines
3.5 KiB
Fortran
130 lines
3.5 KiB
Fortran
!
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! Copyright (C) 2001 PWSCF group
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! This file is distributed under the terms of the
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! GNU General Public License. See the file `License'
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! in the root directory of the present distribution,
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! or http://www.gnu.org/copyleft/gpl.txt .
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!
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!-----------------------------------------------------------------------
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subroutine d3_symdyn (d3dyn, u, ug0, xq, s, invs, rtau, irt, irgq, &
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at, bg, nsymq, nat, irotmq, minus_q, npert_i, npert_f)
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!-----------------------------------------------------------------------
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!
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! This routine symmetrize the dynamical matrix written in the basis
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! of the modes
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!
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!
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#include "f_defs.h"
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USE kinds, only : DP
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implicit none
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integer :: nat, s (3, 3, 48), irt (48, nat), irgq (48), invs (48), &
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nsymq, npert_i, npert_f, irotmq
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! input: the number of atoms
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! input: the symmetry matrices
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! input: the rotated of each atom
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! input: the small group of q
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! input: the inverse of each matrix
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! input: the order of the small gro
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! input: the symmetry q -> -q+G
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real (DP) :: xq (3), rtau (3, 48, nat), at (3, 3), bg (3, 3)
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! input: the coordinates of q
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! input: the R associated at each r
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! input: direct lattice vectors
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! input: reciprocal lattice vectors
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logical :: minus_q
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! input: if true symmetry sends q->
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complex (DP) :: d3dyn (3 * nat, 3 * nat, 3 * nat), &
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ug0 (3 * nat, 3 * nat), u (3 * nat, 3 * nat)
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! inp/out: matrix to symmetr
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! input: the q=0 patterns
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! input: the patterns
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integer :: i, j, i1, icart, jcart, kcart, na, nb, nc, mu, nu, om
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! counters
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complex (DP) :: work, wrk (3, 3)
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! auxiliary variables
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complex (DP), allocatable :: phi (:,:,:,:,:,:)
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! the dynamical matrix
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allocate (phi( 3, 3, 3, nat, nat, nat))
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!
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! First we transform in the cartesian coordinates
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!
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phi = (0.d0, 0.d0)
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do i1 = npert_i, npert_f
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nc = (i1 - 1) / 3 + 1
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kcart = i1 - 3 * (nc - 1)
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do i = 1, 3 * nat
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na = (i - 1) / 3 + 1
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icart = i - 3 * (na - 1)
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do j = 1, 3 * nat
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nb = (j - 1) / 3 + 1
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jcart = j - 3 * (nb - 1)
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work = (0.d0, 0.d0)
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do om = 1, 3 * nat
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do mu = 1, 3 * nat
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do nu = 1, 3 * nat
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work = work + CONJG(ug0 (i1, om) ) * u (i, mu) * &
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d3dyn (om, mu, nu) * CONJG(u (j, nu) )
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enddo
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enddo
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enddo
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phi (kcart, icart, jcart, nc, na, nb) = work
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enddo
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enddo
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enddo
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#ifdef __PARA
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call poolreduce (2 * 27 * nat * nat * nat, phi)
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#endif
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!
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! Then we transform to the crystal axis
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!
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do nc = 1, nat
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do na = 1, nat
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do nb = 1, nat
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call trntnsc_3 (phi (1, 1, 1, nc, na, nb), at, bg, - 1)
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enddo
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enddo
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enddo
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!
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! And we symmetrize in this basis
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!
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call d3_symdynph (xq, phi, s, invs, rtau, irt, irgq, nsymq, nat, &
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irotmq, minus_q)
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!
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! Back to cartesian coordinates
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!
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do nc = 1, nat
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do na = 1, nat
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do nb = 1, nat
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call trntnsc_3 (phi (1, 1, 1, nc, na, nb), at, bg, + 1)
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enddo
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enddo
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enddo
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!
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! rewrite the dynamical matrix on the array dyn with dimension 3nat x 3
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!
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do i1 = 1, 3 * nat
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nc = (i1 - 1) / 3 + 1
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kcart = i1 - 3 * (nc - 1)
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do i = 1, 3 * nat
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na = (i - 1) / 3 + 1
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icart = i - 3 * (na - 1)
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do j = 1, 3 * nat
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nb = (j - 1) / 3 + 1
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jcart = j - 3 * (nb - 1)
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d3dyn (i1, i, j) = phi (kcart, icart, jcart, nc, na, nb)
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enddo
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enddo
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enddo
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deallocate (phi)
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return
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end subroutine d3_symdyn
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