mirror of https://gitlab.com/QEF/q-e.git
569 lines
21 KiB
Fortran
569 lines
21 KiB
Fortran
!
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! Copyright (C) 2001-2004 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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! this routine is used to calculate the electronic polarization
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! when a finite electric field, described through the modern
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! theory of the polarization, is applied.
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! It is very similar to the routine c_phase in bp_c_phase
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! however the numbering of the k-points in the strings is different
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!======================================================================!
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SUBROUTINE c_phase_field(el_pola,ion_pola, fact_pola, pdir)
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!----------------------------------------------------------------------!
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! Geometric phase calculation along a strip of nppstr_3d(pdir) k-points
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! averaged over a 2D grid of nkort k-points ortogonal to nppstr_3d(pdir)
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! --- Make use of the module with common information ---
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USE kinds, ONLY : DP
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USE io_global, ONLY : stdout
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USE io_files, ONLY : iunwfc, nwordwfc
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USE buffers, ONLY : get_buffer
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USE ions_base, ONLY : nat, ntyp => nsp, ityp, tau, zv, atm
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USE cell_base, ONLY : at, alat, tpiba, omega, tpiba2
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USE constants, ONLY : pi, tpi
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USE gvect, ONLY : ngm, nr1, nr2, nr3, nrx1, nrx2, nrx3, &
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ecutwfc, g, gcutm, ngm_g
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USE uspp, ONLY : nkb, vkb, okvan
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USE uspp_param, ONLY : upf, lmaxq, nbetam, nh, nhm
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USE lsda_mod, ONLY : nspin
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USE klist, ONLY : nelec, degauss, nks, xk, wk
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USE wvfct, ONLY : npwx, npw, nbnd
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USE wavefunctions_module, ONLY : evc
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USE bp, ONLY : nppstr_3d, mapgm_global, nx_el
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USE fixed_occ
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USE reciprocal_vectors, ONLY : ig_l2g
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USE mp, ONLY : mp_sum
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USE mp_global, ONLY : intra_pool_comm
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USE becmod, ONLY : calbec
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! --- Avoid implicit definitions ---
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IMPLICIT NONE
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REAL(kind=DP), INTENT(out) :: el_pola!in output electronic polarization
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REAL(kind=DP), INTENT(out) :: ion_pola!in output ionic polarization
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REAL(kind=DP), INTENT(out) :: fact_pola!in outout the prefactor of the polarization
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INTEGER, INTENT(in) :: pdir!direction on which the polarization is calculated
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! --- Internal definitions ---
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INTEGER :: i
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INTEGER :: igk1(npwx)
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INTEGER :: igk0(npwx)
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INTEGER :: ig
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INTEGER :: info
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INTEGER :: is
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INTEGER :: istring
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INTEGER :: iv
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INTEGER :: ivpt(nbnd)
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INTEGER :: j
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INTEGER :: jkb
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INTEGER :: jkb_bp
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INTEGER :: jkb1
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INTEGER :: jv
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INTEGER :: kort
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INTEGER :: kpar
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INTEGER :: kpoint
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INTEGER :: kstart
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INTEGER :: mb
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INTEGER :: mk1
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INTEGER :: mk2
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INTEGER :: mk3
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INTEGER , ALLOCATABLE :: mod_elec(:)
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INTEGER , ALLOCATABLE :: ln(:,:,:)
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INTEGER :: n1
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INTEGER :: n2
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INTEGER :: n3
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INTEGER :: na
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INTEGER :: nb
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INTEGER :: ng
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INTEGER :: nhjkb
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INTEGER :: nhjkbm
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INTEGER :: nkbtona(nkb)
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INTEGER :: nkbtonh(nkb)
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INTEGER :: nkort
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INTEGER :: np
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INTEGER :: npw1
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INTEGER :: npw0
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INTEGER :: nstring
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INTEGER :: nt
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REAL(dp) :: dk(3)
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REAL(dp) :: dkmod
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REAL(dp) :: el_loc
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REAL(dp) :: eps
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REAL(dp) :: fac
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REAL(dp) :: g2kin_bp(npwx)
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REAL(dp) :: gpar(3)
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REAL(dp) :: gtr(3)
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REAL(dp) :: gvec
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REAL(dp), ALLOCATABLE :: loc_k(:)
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REAL(dp), ALLOCATABLE :: pdl_elec(:)
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REAL(dp), ALLOCATABLE :: phik(:)
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REAL(dp) :: qrad_dk(nbetam,nbetam,lmaxq,ntyp)
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REAL(dp) :: weight
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REAL(dp) :: pola, pola_ion
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REAL(dp), ALLOCATABLE :: wstring(:)
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REAL(dp) :: ylm_dk(lmaxq*lmaxq)
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REAL(dp) :: zeta_mod
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COMPLEX(dp), ALLOCATABLE :: aux(:)
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COMPLEX(dp), ALLOCATABLE :: aux0(:)
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COMPLEX(dp) :: becp0(nkb,nbnd)
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COMPLEX(dp) :: becp_bp(nkb,nbnd)
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COMPLEX(dp) , ALLOCATABLE :: cphik(:)
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COMPLEX(dp) :: det
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COMPLEX(dp) :: mat(nbnd,nbnd)
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COMPLEX(dp) :: pref
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COMPLEX(dp) :: q_dk(nhm,nhm,ntyp)
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COMPLEX(dp) :: struc(nat)
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COMPLEX(dp) :: zdotc
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COMPLEX(dp) :: zeta
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COMPLEX(dp), ALLOCATABLE :: psi(:,:)
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COMPLEX(dp), ALLOCATABLE :: psi1(:,:)
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COMPLEX(dp) :: zeta_loc
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LOGICAL l_cal!flag for doing mat calculation
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INTEGER, ALLOCATABLE :: map_g(:)
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REAL(dp) :: dkfact
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COMPLEX(dp) :: zeta_tot
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LOGICAL :: l_para! if true new parallel treatment
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COMPLEX(kind=DP) :: sca
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COMPLEX(kind=DP), ALLOCATABLE :: aux_g(:)
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! ------------------------------------------------------------------------- !
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! INITIALIZATIONS
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! ------------------------------------------------------------------------- !
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ALLOCATE (psi1(npwx,nbnd))
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ALLOCATE (psi(npwx,nbnd))
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ALLOCATE (aux(ngm))
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ALLOCATE (aux0(ngm))
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ALLOCATE (map_g(npwx))
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if(pdir==3) then
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l_para=.false.
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else
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l_para=.true.
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endif
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pola=0.d0 !set to 0 electronic polarization
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zeta_tot=(1.d0,0.d0)
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! --- Check that we are working with an insulator with no empty bands ---
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IF ((degauss > 0.01d0) .OR. (nbnd /= nelec/2)) &
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WRITE (stdout,*) 'PAY ATTENTION: EL FIELD AND OCCUPATIONS'
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! CALL errore('c_phase', &
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! 'Polarization only for insulators and no empty bands',1)
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! --- Define a small number ---
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eps=1.0E-6_dp
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! --- Recalculate FFT correspondence (see ggen.f90) ---
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ALLOCATE (ln (-nr1:nr1, -nr2:nr2, -nr3:nr3) )
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DO ng=1,ngm
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mk1=nint(g(1,ng)*at(1,1)+g(2,ng)*at(2,1)+g(3,ng)*at(3,1))
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mk2=nint(g(1,ng)*at(1,2)+g(2,ng)*at(2,2)+g(3,ng)*at(3,2))
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mk3=nint(g(1,ng)*at(1,3)+g(2,ng)*at(2,3)+g(3,ng)*at(3,3))
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ln(mk1,mk2,mk3) = ng
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END DO
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if (okvan) then
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! --- Initialize arrays ---
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jkb_bp=0
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DO nt=1,ntyp
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DO na=1,nat
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IF (ityp(na).eq.nt) THEN
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DO i=1, nh(nt)
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jkb_bp=jkb_bp+1
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nkbtona(jkb_bp) = na
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nkbtonh(jkb_bp) = i
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END DO
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END IF
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END DO
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END DO
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endif
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! --- Get the number of strings ---
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nstring=nks/nppstr_3d(pdir)
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nkort=nstring/(nspin)
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! --- Allocate memory for arrays ---
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ALLOCATE(phik(nstring))
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ALLOCATE(loc_k(nstring))
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ALLOCATE(cphik(nstring))
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ALLOCATE(wstring(nstring))
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ALLOCATE(pdl_elec(nstring))
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ALLOCATE(mod_elec(nstring))
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! ------------------------------------------------------------------------- !
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! electronic polarization: set values for k-points strings !
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! ------------------------------------------------------------------------- !
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! --- Find vector along strings ---
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if(nppstr_3d(pdir) .ne. 1) then
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gpar(1)=(xk(1,nx_el(nppstr_3d(pdir),pdir))-xk(1,nx_el(1,pdir)))*&
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&DBLE(nppstr_3d(pdir))/DBLE(nppstr_3d(pdir)-1)
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gpar(2)=(xk(2,nx_el(nppstr_3d(pdir),pdir))-xk(2,nx_el(1,pdir)))*&
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&DBLE(nppstr_3d(pdir))/DBLE(nppstr_3d(pdir)-1)
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gpar(3)=(xk(3,nx_el(nppstr_3d(pdir),pdir))-xk(3,nx_el(1,pdir)))*&
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&DBLE(nppstr_3d(pdir))/DBLE(nppstr_3d(pdir)-1)
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gvec=dsqrt(gpar(1)**2+gpar(2)**2+gpar(3)**2)*tpiba
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else
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gpar(1)=0.d0
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gpar(2)=0.d0
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gpar(3)=0.d0
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gpar(pdir)=1.d0/at(pdir,pdir)!
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gvec=tpiba/sqrt(at(pdir,1)**2.d0+at(pdir,2)**2.d0+at(pdir,3)**2.d0)
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endif
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! --- Find vector between consecutive points in strings ---
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if(nppstr_3d(pdir).ne.1) then ! orthorhombic cell
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dk(1)=xk(1,nx_el(2,pdir))-xk(1,nx_el(1,pdir))
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dk(2)=xk(2,nx_el(2,pdir))-xk(2,nx_el(1,pdir))
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dk(3)=xk(3,nx_el(2,pdir))-xk(3,nx_el(1,pdir))
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dkmod=SQRT(dk(1)**2+dk(2)**2+dk(3)**2)*tpiba
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else ! Gamma point case, only cubic cell for now
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dk(1)=0.d0
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dk(2)=0.d0
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dk(3)=0.d0
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dk(pdir)=1.d0/at(pdir,pdir)
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dkmod=tpiba/sqrt(at(pdir,1)**2.d0+at(pdir,2)**2.d0+at(pdir,3)**2.d0)
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endif
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! ------------------------------------------------------------------------- !
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! electronic polarization: weight strings !
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! ------------------------------------------------------------------------- !
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! --- Calculate string weights, normalizing to 1 (no spin) or 1+1 (spin) ---
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DO is=1,nspin
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weight=0.0_dp
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DO kort=1,nkort
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istring=kort+(is-1)*nkort
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wstring(istring)=wk(nppstr_3d(pdir)*istring)
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weight=weight+wstring(istring)
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END DO
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DO kort=1,nkort
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istring=kort+(is-1)*nkort
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wstring(istring)=wstring(istring)/weight
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END DO
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END DO
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! ------------------------------------------------------------------------- !
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! electronic polarization: structure factor !
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! ------------------------------------------------------------------------- !
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! --- Calculate structure factor e^{-i dk*R} ---
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DO na=1,nat
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fac=(dk(1)*tau(1,na)+dk(2)*tau(2,na)+dk(3)*tau(3,na))*tpi
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struc(na)=CMPLX(cos(fac),-sin(fac),kind=DP)
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END DO
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! ------------------------------------------------------------------------- !
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! electronic polarization: form factor !
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! ------------------------------------------------------------------------- !
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if(okvan) then
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! --- Calculate Bessel transform of Q_ij(|r|) at dk [Q_ij^L(|r|)] ---
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CALL calc_btq(dkmod,qrad_dk,0)
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! --- Calculate the q-space real spherical harmonics at dk [Y_LM] ---
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dkmod = dk(1)**2+dk(2)**2+dk(3)**2
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CALL ylmr2(lmaxq*lmaxq, 1, dk, dkmod, ylm_dk)
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! --- Form factor: 4 pi sum_LM c_ij^LM Y_LM(Omega) Q_ij^L(|r|) ---
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q_dk=(0.d0,0.d0)
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DO np =1, ntyp
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if( upf(np)%tvanp ) then
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DO iv = 1, nh(np)
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DO jv = iv, nh(np)
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call qvan3(iv,jv,np,pref,ylm_dk,qrad_dk)
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q_dk(iv,jv,np) = omega*pref
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q_dk(jv,iv,np) = omega*pref
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ENDDO
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ENDDO
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endif
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ENDDO
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endif
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! ------------------------------------------------------------------------- !
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! electronic polarization: strings phases !
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! ------------------------------------------------------------------------- !
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el_loc=0.d0
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kpoint=0
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zeta=(1.d0,0.d0)
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! --- Start loop over spin ---
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DO is=1,nspin
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! --- Start loop over orthogonal k-points ---
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DO kort=1,nkort
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zeta_loc=(1.d0,0.d0)
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! --- Index for this string ---
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istring=kort+(is-1)*nkort
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! --- Initialize expectation value of the phase operator ---
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zeta_mod = 1.d0
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! --- Start loop over parallel k-points ---
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DO kpar = 1,nppstr_3d(pdir)+1
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! --- Set index of k-point ---
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kpoint = kpoint + 1
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! --- Calculate dot products between wavefunctions and betas ---
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IF (kpar /= 1 ) THEN
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! --- Dot wavefunctions and betas for PREVIOUS k-point ---
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CALL gk_sort(xk(1,nx_el(kpoint-1,pdir)),ngm,g,ecutwfc/tpiba2, &
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npw0,igk0,g2kin_bp)
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CALL get_buffer (psi,nwordwfc,iunwfc,nx_el(kpoint-1,pdir))
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if (okvan) then
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CALL init_us_2 (npw0,igk0,xk(1,nx_el(kpoint-1,pdir)),vkb)
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CALL calbec( npw0, vkb, psi, becp0)
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endif
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! --- Dot wavefunctions and betas for CURRENT k-point ---
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IF (kpar /= (nppstr_3d(pdir)+1)) THEN
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CALL gk_sort(xk(1,nx_el(kpoint,pdir)),ngm,g,ecutwfc/tpiba2, &
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npw1,igk1,g2kin_bp)
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CALL get_buffer (psi1,nwordwfc,iunwfc,nx_el(kpoint,pdir))
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if(okvan) then
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CALL init_us_2 (npw1,igk1,xk(1,nx_el(kpoint,pdir)),vkb)
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CALL calbec( npw1, vkb, psi1, becp_bp)
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endif
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ELSE
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kstart = kpoint-(nppstr_3d(pdir)+1)+1
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CALL gk_sort(xk(1,nx_el(kstart,pdir)),ngm,g,ecutwfc/tpiba2, &
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npw1,igk1,g2kin_bp)
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CALL get_buffer (psi1,nwordwfc,iunwfc,nx_el(kstart,pdir))
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if(okvan) then
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CALL init_us_2 (npw1,igk1,xk(1,nx_el(kstart,pdir)),vkb)
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CALL calbec( npw1, vkb, psi1, becp_bp)
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endif
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ENDIF
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! --- Matrix elements calculation ---
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IF (kpar == (nppstr_3d(pdir)+1) .and. .not.l_para) THEN
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map_g(:) = 0
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do ig=1,npw1
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! --- If k'=k+G_o, the relation psi_k+G_o (G-G_o) ---
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! --- = psi_k(G) is used, gpar=G_o, gtr = G-G_o ---
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gtr(1)=g(1,igk1(ig)) - gpar(1)
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gtr(2)=g(2,igk1(ig)) - gpar(2)
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gtr(3)=g(3,igk1(ig)) - gpar(3)
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! --- Find crystal coordinates of gtr, n1,n2,n3 ---
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! --- and the position ng in the ngm array ---
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IF (gtr(1)**2+gtr(2)**2+gtr(3)**2 <= gcutm) THEN
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n1=NINT(gtr(1)*at(1,1)+gtr(2)*at(2,1) &
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+gtr(3)*at(3,1))
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n2=NINT(gtr(1)*at(1,2)+gtr(2)*at(2,2) &
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+gtr(3)*at(3,2))
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n3=NINT(gtr(1)*at(1,3)+gtr(2)*at(2,3) &
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+gtr(3)*at(3,3))
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ng=ln(n1,n2,n3)
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IF ( (ABS(g(1,ng)-gtr(1)) > eps) .OR. &
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(ABS(g(2,ng)-gtr(2)) > eps) .OR. &
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(ABS(g(3,ng)-gtr(3)) > eps) ) THEN
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WRITE(6,*) ' error: translated G=', &
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gtr(1),gtr(2),gtr(3), &
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& ' with crystal coordinates',n1,n2,n3, &
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& ' corresponds to ng=',ng,' but G(ng)=', &
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& g(1,ng),g(2,ng),g(3,ng)
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WRITE(6,*) ' probably because G_par is NOT', &
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& ' a reciprocal lattice vector '
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WRITE(6,*) ' Possible choices as smallest ', &
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' G_par:'
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DO i=1,50
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WRITE(6,*) ' i=',i,' G=', &
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g(1,i),g(2,i),g(3,i)
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ENDDO
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STOP
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ENDIF
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ELSE
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WRITE(6,*) ' |gtr| > gcutm for gtr=', &
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gtr(1),gtr(2),gtr(3)
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STOP
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END IF
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map_g(ig)=ng
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enddo
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ENDIF
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mat=(0.d0,0.d0)
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DO nb=1,nbnd
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DO mb=1,nbnd
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! added support for spin polarized case
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l_cal=.true.
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if( nspin==2 .and. tfixed_occ) then
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if(f_inp(nb,is)==0.d0 .or. f_inp(mb,is)==0.d0) then
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l_cal=.false.
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if(nb==mb) then
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mat(nb,mb)=1.d0
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else
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mat(nb,mb)=0.d0
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endif
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endif
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endif
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if(l_cal) then
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aux=(0.d0,0.d0)
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aux0=(0.d0,0.d0)
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DO ig=1,npw0
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aux0(igk0(ig))=psi(ig,nb)
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END DO
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IF (kpar /= (nppstr_3d(pdir)+1)) THEN
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do ig=1,npw1
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aux(igk1(ig))=psi1(ig,mb)
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enddo
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ELSE IF( .not. l_para) THEN
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do ig=1,npw1
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aux(map_g(ig))=psi1(ig,mb)
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enddo
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ELSE
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! allocate global array
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allocate(aux_g(ngm_g))
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aux_g=(0.d0,0.d0)
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! put psi1 on global array
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do ig=1,npw1
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|
aux_g(mapgm_global(ig_l2g(igk1(ig)),pdir))=psi1(ig,mb)
|
|
enddo
|
|
call mp_sum(aux_g(:))
|
|
sca=(0.d0,0.d0)
|
|
! do scalar product
|
|
do ig=1,ngm
|
|
sca=sca+conjg(aux0(ig))*aux_g(ig_l2g(ig))
|
|
enddo
|
|
! do mp_sum
|
|
call mp_sum(sca)
|
|
mat(nb,mb)=sca
|
|
deallocate(aux_g)
|
|
ENDIF
|
|
|
|
if(kpar /= (nppstr_3d(pdir)+1).or..not. l_para) then
|
|
mat(nb,mb) = zdotc(ngm,aux0,1,aux,1)
|
|
call mp_sum( mat(nb,mb), intra_pool_comm )
|
|
endif
|
|
! --- Calculate the augmented part: ij=KB projectors, ---
|
|
! --- R=atom index: SUM_{ijR} q(ijR) <u_nk|beta_iR> ---
|
|
! --- <beta_jR|u_mk'> e^i(k-k')*R = ---
|
|
! --- also <u_nk|beta_iR>=<psi_nk|beta_iR> = becp^* ---
|
|
if(okvan) then
|
|
pref = (0.d0,0.d0)
|
|
DO jkb=1,nkb
|
|
nhjkb = nkbtonh(jkb)
|
|
na = nkbtona(jkb)
|
|
np = ityp(na)
|
|
nhjkbm = nh(np)
|
|
jkb1 = jkb - nhjkb
|
|
DO j = 1,nhjkbm
|
|
pref = pref+CONJG(becp0(jkb,nb))*becp_bp(jkb1+j,mb) &
|
|
*q_dk(nhjkb,j,np)*struc(na)
|
|
ENDDO
|
|
ENDDO
|
|
|
|
mat(nb,mb) = mat(nb,mb) + pref
|
|
endif
|
|
endif !on l_cal
|
|
ENDDO
|
|
ENDDO
|
|
|
|
! --- Calculate matrix determinant ---
|
|
|
|
call ZGETRF(nbnd,nbnd,mat,nbnd,ivpt,info)
|
|
CALL errore('c_phase','error in zgetrf',abs(info))
|
|
det=(1.d0,0.d0)
|
|
do nb=1,nbnd
|
|
if(nb.ne.ivpt(nb)) det=-det
|
|
det = det*mat(nb,nb)
|
|
enddo
|
|
! --- Multiply by the already calculated determinants ---
|
|
zeta=zeta*det
|
|
zeta_loc=zeta_loc*det
|
|
|
|
! --- End of dot products between wavefunctions and betas ---
|
|
ENDIF
|
|
|
|
! --- End loop over parallel k-points ---
|
|
END DO
|
|
zeta_tot=zeta_tot*(zeta_loc**wstring(istring))
|
|
pola=pola+wstring(istring)*aimag(log(zeta_loc))
|
|
|
|
kpoint=kpoint-1
|
|
! --- Calculate the phase for this string ---
|
|
phik(istring)=AIMAG(LOG(zeta))
|
|
cphik(istring)=COS(phik(istring))*(1.0_dp,0.0_dp) &
|
|
+SIN(phik(istring))*(0.0_dp,1.0_dp)
|
|
|
|
! --- Calculate the localization for current kort ---
|
|
zeta_mod= DBLE(CONJG(zeta)*zeta)
|
|
loc_k(istring)= - (nppstr_3d(pdir)-1) / gvec**2 / nbnd *log(zeta_mod)
|
|
|
|
! --- End loop over orthogonal k-points ---
|
|
END DO
|
|
|
|
! --- End loop over spin ---
|
|
END DO
|
|
!-----calculate polarization
|
|
!-----the factor 2. is because of spin
|
|
!new system for avoiding phases problem
|
|
pola=aimag(log(zeta_tot))
|
|
|
|
if(nspin==1) pola=pola*2.d0
|
|
!pola=pola/(gpar(pdir)*tpiba)
|
|
call factor_a(pdir,at,dkfact)
|
|
!factor sqrt(2) is the electronic charge in Rydberg units
|
|
pola=pola*dsqrt(2.d0)/tpiba*dkfact
|
|
|
|
!write output
|
|
write(stdout,*)
|
|
write(stdout,*) " Expectation value of exp(iGx):",zeta_tot,dkfact
|
|
write(stdout,*) " Electronic Dipole per cell (Ry a.u.)",pola
|
|
|
|
! ------------------------------------------------------------------------- !
|
|
! ionic polarization !
|
|
! ------------------------------------------------------------------------- !
|
|
|
|
!factor sqrt(2) is the electronic charge in Rydberg units
|
|
pola_ion=0.d0
|
|
DO na=1,nat
|
|
pola_ion=pola_ion+zv(ityp(na))*tau(pdir,na)*alat*dsqrt(2.d0)
|
|
END DO
|
|
|
|
write(stdout,*) " Ionic Dipole per cell (Ry a.u.)",pola_ion
|
|
|
|
|
|
el_pola=pola
|
|
ion_pola=pola_ion
|
|
fact_pola=dsqrt(2.d0)/tpiba*dkfact
|
|
|
|
|
|
! ------------------------------------------------------------------------- !
|
|
|
|
! --- Free memory ---
|
|
DEALLOCATE(pdl_elec)
|
|
DEALLOCATE(mod_elec)
|
|
DEALLOCATE(wstring)
|
|
DEALLOCATE(loc_k)
|
|
DEALLOCATE(phik)
|
|
DEALLOCATE(cphik)
|
|
DEALLOCATE(ln)
|
|
DEALLOCATE(map_g)
|
|
DEALLOCATE(aux)
|
|
DEALLOCATE(aux0)
|
|
DEALLOCATE(psi)
|
|
DEALLOCATE(psi1)
|
|
!------------------------------------------------------------------------------!
|
|
|
|
END SUBROUTINE c_phase_field
|
|
|
|
!==============================================================================!
|