mirror of https://gitlab.com/QEF/q-e.git
4739 lines
146 KiB
Fortran
4739 lines
146 KiB
Fortran
!
|
|
! Copyright (C) 2002-2005 FPMD-CPV groups
|
|
! This file is distributed under the terms of the
|
|
! GNU General Public License. See the file `License'
|
|
! in the root directory of the present distribution,
|
|
! or http://www.gnu.org/copyleft/gpl.txt .
|
|
!
|
|
|
|
#include "f_defs.h"
|
|
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine atomic_wfc(eigr,n_atomic_wfc,wfc)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! Compute atomic wavefunctions in G-space
|
|
!
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart, g, gx
|
|
use ions_base, only: nsp, na, nat
|
|
use cell_base, only: tpiba
|
|
use atom, only: nchi, lchi, mesh, r, chi, rab
|
|
!
|
|
implicit none
|
|
integer, intent(in) :: n_atomic_wfc
|
|
complex(8), intent(in) :: eigr(ngw,nat)
|
|
complex(8), intent(out):: wfc(ngw,n_atomic_wfc)
|
|
!
|
|
integer :: natwfc, ndm, is, ia, ir, nb, l, m, lm, i, lmax_wfc, isa
|
|
real(8), allocatable:: ylm(:,:), q(:), jl(:), vchi(:), &
|
|
& chiq(:)
|
|
!
|
|
! calculate max angular momentum required in wavefunctions
|
|
!
|
|
lmax_wfc=-1
|
|
do is = 1,nsp
|
|
do nb = 1, nchi(is)
|
|
lmax_wfc = max (lmax_wfc, lchi (nb, is) )
|
|
enddo
|
|
enddo
|
|
allocate(ylm(ngw,(lmax_wfc+1)**2))
|
|
call ylmr2 ((lmax_wfc+1)**2, ngw, gx, g, ylm)
|
|
ndm = MAXVAL(mesh(1:nsp))
|
|
allocate(jl(ndm), vchi(ndm))
|
|
allocate(q(ngw), chiq(ngw))
|
|
!
|
|
do i=1,ngw
|
|
q(i) = sqrt(g(i))*tpiba
|
|
end do
|
|
!
|
|
natwfc=0
|
|
isa = 0
|
|
do is=1,nsp
|
|
!
|
|
! radial fourier transform of the chi functions
|
|
! NOTA BENE: chi is r times the radial part of the atomic wavefunction
|
|
!
|
|
do nb = 1,nchi(is)
|
|
l = lchi(nb,is)
|
|
do i=1,ngw
|
|
call sph_bes (mesh(is), r(1,is), q(i), l, jl)
|
|
do ir=1,mesh(is)
|
|
vchi(ir) = chi(ir,nb,is)*r(ir,is)*jl(ir)
|
|
enddo
|
|
call simpson_cp90(mesh(is),vchi,rab(1,is),chiq(i))
|
|
enddo
|
|
!
|
|
! multiply by angular part and structure factor
|
|
! NOTA BENE: the factor i^l MUST be present!!!
|
|
!
|
|
do m = 1,2*l+1
|
|
lm = l**2 + m
|
|
do ia = 1 + isa, na(is) + isa
|
|
natwfc = natwfc + 1
|
|
wfc(:,natwfc) = (0.d0,1.d0)**l * eigr(:,ia)* ylm(:,lm)*chiq(:)
|
|
enddo
|
|
enddo
|
|
enddo
|
|
isa = isa + na(is)
|
|
enddo
|
|
!
|
|
if (natwfc.ne.n_atomic_wfc) &
|
|
& call errore('atomic_wfc','unexpected error',natwfc)
|
|
!
|
|
deallocate(q, chiq, vchi, jl, ylm)
|
|
!
|
|
return
|
|
end subroutine atomic_wfc
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine box2grid(irb,nfft,qv,vr)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! add array qv(r) on box grid to array vr(r) on dense grid
|
|
! irb : position of the box in the dense grid
|
|
! nfft=1 add real part of qv(r) to real part of array vr(r)
|
|
! nfft=2 add imaginary part of qv(r) to real part of array vr(r)
|
|
!
|
|
use parameters, only: natx, nsx
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nnr => nnrx
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nnrb => nnrbx
|
|
use para_mod
|
|
implicit none
|
|
integer, intent(in):: nfft, irb(3)
|
|
real(8), intent(in):: qv(2,nnrb)
|
|
complex(8), intent(inout):: vr(nnr)
|
|
!
|
|
integer ir1, ir2, ir3, ir, ibig1, ibig2, ibig3, ibig
|
|
|
|
if(nfft.le.0.or.nfft.gt.2) call errore('box2grid','wrong data',nfft)
|
|
|
|
do ir3=1,nr3b
|
|
ibig3=irb(3)+ir3-1
|
|
ibig3=1+mod(ibig3-1,nr3)
|
|
if(ibig3.lt.1.or.ibig3.gt.nr3) &
|
|
& call errore('box2grid','ibig3 wrong',ibig3)
|
|
ibig3=ibig3-dfftp%ipp(me)
|
|
if ( ibig3 .gt. 0 .and. ibig3 .le. ( dfftp%npp(me) ) ) then
|
|
do ir2=1,nr2b
|
|
ibig2=irb(2)+ir2-1
|
|
ibig2=1+mod(ibig2-1,nr2)
|
|
if(ibig2.lt.1.or.ibig2.gt.nr2) &
|
|
& call errore('box2grid','ibig2 wrong',ibig2)
|
|
do ir1=1,nr1b
|
|
ibig1=irb(1)+ir1-1
|
|
ibig1=1+mod(ibig1-1,nr1)
|
|
if(ibig1.lt.1.or.ibig1.gt.nr1) &
|
|
& call errore('box2grid','ibig1 wrong',ibig1)
|
|
ibig=ibig1+(ibig2-1)*nr1x+(ibig3-1)*nr1x*nr2x
|
|
ir=ir1+(ir2-1)*nr1bx+(ir3-1)*nr1bx*nr2bx
|
|
vr(ibig) = vr(ibig)+qv(nfft,ir)
|
|
end do
|
|
end do
|
|
end if
|
|
end do
|
|
!
|
|
return
|
|
end subroutine box2grid
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine box2grid2(irb,qv,v)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! add array qv(r) on box grid to array v(r) on dense grid
|
|
! irb : position of the box in the dense grid
|
|
!
|
|
use parameters, only: nsx, natx
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nnr => nnrx
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nnrb => nnrbx
|
|
use para_mod
|
|
implicit none
|
|
integer, intent(in):: irb(3)
|
|
complex(8), intent(in):: qv(nnrb)
|
|
complex(8), intent(inout):: v(nnr)
|
|
!
|
|
integer ir1, ir2, ir3, ir, ibig1, ibig2, ibig3, ibig
|
|
|
|
do ir3=1,nr3b
|
|
ibig3=irb(3)+ir3-1
|
|
ibig3=1+mod(ibig3-1,nr3)
|
|
if(ibig3.lt.1.or.ibig3.gt.nr3) &
|
|
& call errore('box2grid2','ibig3 wrong',ibig3)
|
|
ibig3=ibig3-dfftp%ipp(me)
|
|
if (ibig3.gt.0.and.ibig3.le. dfftp%npp(me) ) then
|
|
do ir2=1,nr2b
|
|
ibig2=irb(2)+ir2-1
|
|
ibig2=1+mod(ibig2-1,nr2)
|
|
if(ibig2.lt.1.or.ibig2.gt.nr2) &
|
|
& call errore('box2grid2','ibig2 wrong',ibig2)
|
|
do ir1=1,nr1b
|
|
ibig1=irb(1)+ir1-1
|
|
ibig1=1+mod(ibig1-1,nr1)
|
|
if(ibig1.lt.1.or.ibig1.gt.nr1) &
|
|
& call errore('box2grid2','ibig1 wrong',ibig1)
|
|
ibig=ibig1+(ibig2-1)*nr1x+(ibig3-1)*nr1x*nr2x
|
|
ir=ir1+(ir2-1)*nr1bx+(ir3-1)*nr1bx*nr2bx
|
|
v(ibig) = v(ibig)+qv(ir)
|
|
end do
|
|
end do
|
|
end if
|
|
end do
|
|
|
|
return
|
|
end subroutine box2grid2
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
real(8) function boxdotgrid(irb,nfft,qv,vr)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! Calculate \sum_i qv(r_i)*vr(r_i) with r_i on box grid
|
|
! array qv(r) is defined on box grid, array vr(r)on dense grid
|
|
! irb : position of the box in the dense grid
|
|
! nfft=1 (2): use real (imaginary) part of qv(r)
|
|
! Parallel execution: remember to sum the contributions from other nodes
|
|
!
|
|
use parameters, only: nsx, natx
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nnr => nnrx
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nnrb => nnrbx
|
|
use para_mod
|
|
implicit none
|
|
integer, intent(in):: nfft, irb(3)
|
|
real(8), intent(in):: qv(2,nnrb), vr(nnr)
|
|
!
|
|
integer ir1, ir2, ir3, ir, ibig1, ibig2, ibig3, ibig
|
|
!
|
|
!
|
|
if(nfft.le.0.or.nfft.gt.2) call errore('box2grid','wrong data',nfft)
|
|
|
|
boxdotgrid=0.d0
|
|
|
|
do ir3=1,nr3b
|
|
ibig3=irb(3)+ir3-1
|
|
ibig3=1+mod(ibig3-1,nr3)
|
|
ibig3=ibig3-dfftp%ipp(me)
|
|
if (ibig3.gt.0.and.ibig3.le. dfftp%npp(me) ) then
|
|
do ir2=1,nr2b
|
|
ibig2=irb(2)+ir2-1
|
|
ibig2=1+mod(ibig2-1,nr2)
|
|
do ir1=1,nr1b
|
|
ibig1=irb(1)+ir1-1
|
|
ibig1=1+mod(ibig1-1,nr1)
|
|
ibig=ibig1 + (ibig2-1)*nr1x + (ibig3-1)*nr1x*nr2x
|
|
ir =ir1 + (ir2-1)*nr1bx + (ir3-1)*nr1bx*nr2bx
|
|
boxdotgrid = boxdotgrid + qv(nfft,ir)*vr(ibig)
|
|
end do
|
|
end do
|
|
endif
|
|
end do
|
|
|
|
return
|
|
end function boxdotgrid
|
|
!
|
|
|
|
|
|
!-------------------------------------------------------------------------
|
|
subroutine calphi(c0,ema0bg,bec,betae,phi)
|
|
!-----------------------------------------------------------------------
|
|
! input: c0 (orthonormal with s(r(t)), bec=<c0|beta>, betae=|beta>
|
|
! computes the matrix phi (with the old positions)
|
|
! where |phi> = s'|c0> = |c0> + sum q_ij |i><j|c0>
|
|
! where s'=s(r(t))
|
|
!
|
|
use ions_base, only: na, nsp
|
|
use io_global, only: stdout
|
|
use cvan, only: ish, nvb
|
|
use uspp_param, only: nh
|
|
use uspp, only :nhsa=>nkb, nhsavb=>nkbus, qq
|
|
use gvecw, only: ngw
|
|
use electrons_base, only: n => nbsp
|
|
use constants, only: pi, fpi
|
|
use control_flags, only: iprint, iprsta
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
complex(8) c0(ngw,n), phi(ngw,n), betae(ngw,nhsa)
|
|
real(8) ema0bg(ngw), bec(nhsa,n), emtot
|
|
! local variables
|
|
integer is, iv, jv, ia, inl, jnl, i, j
|
|
real(8) qtemp(nhsavb,n) ! automatic array
|
|
!
|
|
call start_clock( 'calphi' )
|
|
phi(:,:) = (0.d0, 0.d0)
|
|
!
|
|
if (nvb.gt.0) then
|
|
qtemp (:,:) = 0.d0
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)) > 1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
do i=1,n
|
|
qtemp(inl,i) = qtemp(inl,i) + &
|
|
& qq(iv,jv,is)*bec(jnl,i)
|
|
end do
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
call MXMA &
|
|
& (betae,1,2*ngw,qtemp,1,nhsavb,phi,1,2*ngw,2*ngw,nhsavb,n)
|
|
end if
|
|
!
|
|
do j=1,n
|
|
do i=1,ngw
|
|
phi(i,j)=(phi(i,j)+c0(i,j))*ema0bg(i)
|
|
end do
|
|
end do
|
|
! =================================================================
|
|
if(iprsta > 2) then
|
|
emtot=0.
|
|
do j=1,n
|
|
do i=1,ngw
|
|
emtot=emtot &
|
|
& +2.*DBLE(phi(i,j)*CONJG(c0(i,j)))*ema0bg(i)**(-2.)
|
|
end do
|
|
end do
|
|
emtot=emtot/n
|
|
|
|
call mp_sum( emtot )
|
|
|
|
WRITE( stdout,*) 'in calphi sqrt(emtot)=',sqrt(emtot)
|
|
WRITE( stdout,*)
|
|
do is=1,nsp
|
|
if(nsp > 1) then
|
|
WRITE( stdout,'(33x,a,i4)') ' calphi: bec (is)',is
|
|
WRITE( stdout,'(8f9.4)') &
|
|
& ((bec(ish(is)+(iv-1)*na(is)+1,i),iv=1,nh(is)),i=1,n)
|
|
else
|
|
do ia=1,na(is)
|
|
WRITE( stdout,'(33x,a,i4)') ' calphi: bec (ia)',ia
|
|
WRITE( stdout,'(8f9.4)') &
|
|
& ((bec(ish(is)+(iv-1)*na(is)+ia,i),iv=1,nh(is)),i=1,n)
|
|
end do
|
|
end if
|
|
end do
|
|
endif
|
|
call stop_clock( 'calphi' )
|
|
!
|
|
return
|
|
end subroutine calphi
|
|
!-----------------------------------------------------------------------
|
|
real(8) function cscnorm(bec,cp,i)
|
|
!-----------------------------------------------------------------------
|
|
! requires in input the updated bec(i)
|
|
!
|
|
use ions_base, only: na
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use electrons_base, only: n => nbsp
|
|
use cvan, only: ish, nvb
|
|
use uspp_param, only: nh
|
|
use uspp, only: nhsa=>nkb, nhsavb=>nkbus, qq
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
integer i
|
|
real(8) bec(nhsa,n)
|
|
complex(8) cp(ngw,n)
|
|
!
|
|
integer ig, is, iv, jv, ia, inl, jnl
|
|
real(8) rsum
|
|
real(8), allocatable:: temp(:)
|
|
!
|
|
!
|
|
allocate(temp(ngw))
|
|
do ig=1,ngw
|
|
temp(ig)=DBLE(CONJG(cp(ig,i))*cp(ig,i))
|
|
end do
|
|
rsum=2.*SUM(temp)
|
|
if (gstart == 2) rsum=rsum-temp(1)
|
|
|
|
call mp_sum( rsum )
|
|
|
|
deallocate(temp)
|
|
!
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
rsum = rsum + &
|
|
& qq(iv,jv,is)*bec(inl,i)*bec(jnl,i)
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
cscnorm=sqrt(rsum)
|
|
!
|
|
return
|
|
end function cscnorm
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine denkin(c,dekin)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
use constants, only: pi, fpi
|
|
use electrons_base, only: n => nbsp, nx => nbspx, f
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart, g, gx
|
|
use cell_base, only: ainv, tpiba2
|
|
use gvecw, only: ggp, ecutz, ecsig, ecfix
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
! input
|
|
complex(8) c(ngw,nx)
|
|
! output
|
|
real(8) dekin(3,3)
|
|
! local
|
|
integer j, k, ig, i
|
|
real(8), allocatable:: gtmp(:)
|
|
real(8) sk(n) ! automatic array
|
|
real(8) :: ga, dggp, efac
|
|
!
|
|
allocate (gtmp(ngw))
|
|
dekin=0.d0
|
|
do j=1,3
|
|
do k=1,3
|
|
do ig=1,ngw
|
|
efac = 2.d0 * ecutz / ecsig / sqrt(pi)
|
|
dggp = 1.d0 + efac * exp( - ( tpiba2 * g(ig) - ecfix ) * ( tpiba2 * g(ig) - ecfix ) / ecsig / ecsig )
|
|
ga = gx(1,ig) * ainv(k,1) + gx(2,ig) * ainv(k,2) + gx(3,ig) * ainv(k,3)
|
|
gtmp(ig) = gx(j,ig) * ga * dggp
|
|
end do
|
|
do i=1,n
|
|
sk(i)=0.d0
|
|
do ig=gstart,ngw
|
|
sk(i)=sk(i)+DBLE(CONJG(c(ig,i))*c(ig,i))*gtmp(ig)
|
|
end do
|
|
end do
|
|
do i=1,n
|
|
dekin(j,k)=dekin(j,k)-2.d0*tpiba2*(f(i)*sk(i))
|
|
end do
|
|
end do
|
|
end do
|
|
deallocate (gtmp)
|
|
|
|
call mp_sum( dekin( 1:3, 1:3 ) )
|
|
!
|
|
return
|
|
end subroutine denkin
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine denh(rhotmp,drhotmp,sfac,vtemp,eh,dh)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! derivative of hartree energy wrt cell parameters h
|
|
! Output in dh
|
|
!
|
|
! rhotmp input : total electronic + ionic broadened charge (G)
|
|
! drhotmp input and work space
|
|
! sfac input : structure factors
|
|
! wtemp work space
|
|
! eh input: hartree energy
|
|
!
|
|
use constants, only: pi, fpi
|
|
use ions_base, only: nsp
|
|
use gvecs
|
|
use gvecp, only: ng => ngm
|
|
use reciprocal_vectors, only: gstart, gx, g
|
|
use cell_base, only: omega
|
|
use cell_base, only: ainv, tpiba2
|
|
use local_pseudo, only: rhops, drhops
|
|
use mp, only: mp_sum
|
|
|
|
implicit none
|
|
! input
|
|
complex(8) rhotmp(ng), drhotmp(ng,3,3), vtemp(ng), sfac(ngs,nsp)
|
|
real(8) eh
|
|
! output
|
|
real(8) dh(3,3)
|
|
! local
|
|
integer i, j, ig, is
|
|
real(8) wz
|
|
!
|
|
! wz = factor for g.neq.0 because of c*(g)=c(-g)
|
|
!
|
|
wz=2.d0
|
|
do j=1,3
|
|
do i=1,3
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
drhotmp(ig,i,j) = drhotmp(ig,i,j) - &
|
|
& sfac(ig,is)*drhops(ig,is)* &
|
|
& 2.d0*tpiba2*gx(i,ig)*(gx(1,ig)*ainv(j,1)+ &
|
|
& gx(2,ig)*ainv(j,2)+gx(3,ig)*ainv(j,3))- &
|
|
& sfac(ig,is)*rhops(ig,is)*ainv(j,i)
|
|
enddo
|
|
enddo
|
|
if (gstart == 2) vtemp(1)=(0.d0,0.d0)
|
|
do ig=gstart,ng
|
|
vtemp(ig)=CONJG(rhotmp(ig))*rhotmp(ig)/(tpiba2*g(ig))**2 &
|
|
& * tpiba2*gx(i,ig)*(gx(1,ig)*ainv(j,1)+ &
|
|
& gx(2,ig)*ainv(j,2)+gx(3,ig)*ainv(j,3)) + &
|
|
& CONJG(rhotmp(ig))/(tpiba2*g(ig))*drhotmp(ig,i,j)
|
|
enddo
|
|
dh(i,j)=fpi*omega*DBLE(SUM(vtemp))*wz
|
|
enddo
|
|
enddo
|
|
|
|
call mp_sum( dh( 1:3, 1:3 ) )
|
|
|
|
do i=1,3
|
|
do j=1,3
|
|
dh(i,j)=dh(i,j)+omega*eh*ainv(j,i)
|
|
end do
|
|
end do
|
|
|
|
return
|
|
end subroutine denh
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine denps(rhotmp,drhotmp,sfac,vtemp,dps)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! derivative of local potential energy wrt cell parameters h
|
|
! Output in dps
|
|
!
|
|
! rhotmp input : rho(G) (up and down spin components summed)
|
|
! drhotmp input
|
|
! sfac input : structure factors
|
|
! wtemp work space
|
|
!
|
|
use ions_base, only: nsp
|
|
use gvecs, only: ngs
|
|
use gvecp, only: ng => ngm
|
|
use reciprocal_vectors, only: gstart, gx
|
|
use cell_base, only: omega
|
|
use cell_base, only: ainv, tpiba2
|
|
use local_pseudo, only: vps, dvps
|
|
use mp, only: mp_sum
|
|
|
|
implicit none
|
|
! input
|
|
complex(8) rhotmp(ng), drhotmp(ng,3,3), vtemp(ng), sfac(ngs,nsp)
|
|
! output
|
|
real(8) dps(3,3)
|
|
! local
|
|
integer i, j, ig, is
|
|
real(8) wz
|
|
!
|
|
! wz = factor for g.neq.0 because of c*(g)=c(-g)
|
|
!
|
|
wz=2.d0
|
|
do i=1,3
|
|
do j=1,3
|
|
do ig=1,ngs
|
|
vtemp(ig)=(0.,0.)
|
|
enddo
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
vtemp(ig)=vtemp(ig)-CONJG(rhotmp(ig))*sfac(ig,is)* &
|
|
& dvps(ig,is)*2.d0*tpiba2*gx(i,ig)* &
|
|
& (gx(1,ig)*ainv(j,1) + &
|
|
& gx(2,ig)*ainv(j,2) + &
|
|
& gx(3,ig)*ainv(j,3) ) + &
|
|
& CONJG(drhotmp(ig,i,j))*sfac(ig,is)*vps(ig,is)
|
|
enddo
|
|
enddo
|
|
dps(i,j)=omega*DBLE(wz*SUM(vtemp))
|
|
if (gstart == 2) dps(i,j)=dps(i,j)-omega*DBLE(vtemp(1))
|
|
enddo
|
|
enddo
|
|
|
|
call mp_sum( dps( 1:3, 1:3 ) )
|
|
|
|
return
|
|
end subroutine denps
|
|
|
|
|
|
!-----------------------------------------------------------------------
|
|
subroutine denlcc( nnr, nspin, vxcr, sfac, drhocg, dcc )
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! derivative of non linear core correction exchange energy wrt cell
|
|
! parameters h
|
|
! Output in dcc
|
|
!
|
|
use kinds, only: DP
|
|
use ions_base, only: nsp
|
|
use reciprocal_vectors, only: gstart, gx, ngs, g, ngm
|
|
use recvecs_indexes, only: np
|
|
use cell_base, only: omega, ainv, tpiba2
|
|
use mp, only: mp_sum
|
|
use atom, only: nlcc
|
|
use grid_dimensions, only: nr1, nr2, nr3, nr1x, nr2x, nr3x
|
|
|
|
implicit none
|
|
|
|
! input
|
|
|
|
integer, INTENT(IN) :: nnr, nspin
|
|
real(DP) :: vxcr( nnr, nspin )
|
|
complex(DP) :: sfac( ngs, nsp )
|
|
real(DP) :: drhocg( ngm, nsp )
|
|
|
|
! output
|
|
|
|
real(DP), INTENT(OUT) :: dcc(3,3)
|
|
|
|
! local
|
|
|
|
integer :: i, j, ig, is
|
|
complex(DP) :: srhoc
|
|
real(DP) :: vxcc
|
|
!
|
|
complex(DP), ALLOCATABLE :: vxc( : )
|
|
!
|
|
dcc = 0.0d0
|
|
!
|
|
ALLOCATE( vxc( nnr ) )
|
|
!
|
|
vxc(:) = vxcr(:,1)
|
|
!
|
|
IF( nspin > 1 ) vxc(:) = vxc(:) + vxcr(:,2)
|
|
!
|
|
call fwfft( vxc, nr1, nr2, nr3, nr1x, nr2x, nr3x )
|
|
!
|
|
do i=1,3
|
|
do j=1,3
|
|
do ig = gstart, ngs
|
|
srhoc = 0.0d0
|
|
do is = 1, nsp
|
|
IF( nlcc( is ) ) srhoc = srhoc + sfac( ig, is ) * drhocg( ig, is )
|
|
enddo
|
|
vxcc = DBLE( CONJG( vxc( np( ig ) ) ) * srhoc ) / SQRT( g( ig ) * tpiba2 )
|
|
dcc(i,j) = dcc(i,j) + vxcc * &
|
|
& 2.d0 * tpiba2 * gx(i,ig) * &
|
|
& (gx(1,ig)*ainv(j,1) + &
|
|
& gx(2,ig)*ainv(j,2) + &
|
|
& gx(3,ig)*ainv(j,3) )
|
|
enddo
|
|
enddo
|
|
enddo
|
|
|
|
DEALLOCATE( vxc )
|
|
|
|
dcc = dcc * omega
|
|
|
|
call mp_sum( dcc( 1:3, 1:3 ) )
|
|
|
|
return
|
|
end subroutine denlcc
|
|
|
|
|
|
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine dforce (bec,betae,i,c,ca,df,da,v)
|
|
!-----------------------------------------------------------------------
|
|
!computes: the generalized force df=CMPLX(dfr,dfi) acting on the i-th
|
|
! electron state at the gamma point of the brillouin zone
|
|
! represented by the vector c=CMPLX(cr,ci)
|
|
!
|
|
! d_n(g) = f_n { 0.5 g^2 c_n(g) + [vc_n](g) +
|
|
! sum_i,ij d^q_i,ij (-i)**l beta_i,i(g)
|
|
! e^-ig.r_i < beta_i,j | c_n >}
|
|
use kinds, only: dp
|
|
use control_flags, only: iprint, tbuff
|
|
use gvecs
|
|
use gvecw, only: ngw
|
|
use cvan, only: ish
|
|
use uspp, only: nhsa=>nkb, dvan, deeq
|
|
use uspp_param, only: nhm, nh
|
|
use smooth_grid_dimensions, only: nr1s, nr2s, nr3s, &
|
|
nr1sx, nr2sx, nr3sx, nnrsx
|
|
use electrons_base, only: n => nbsp, ispin => fspin, f, nspin
|
|
use constants, only: pi, fpi
|
|
use ions_base, only: nsp, na, nat
|
|
use gvecw, only: ggp
|
|
use cell_base, only: tpiba2
|
|
use ensemble_dft, only: tens
|
|
use funct, only: ismeta
|
|
!
|
|
implicit none
|
|
!
|
|
complex(8) betae(ngw,nhsa), c(ngw), ca(ngw), df(ngw), da(ngw)
|
|
real(8) bec(nhsa,n), v(nnrsx,nspin)
|
|
integer i
|
|
! local variables
|
|
integer iv, jv, ia, is, isa, ism, ios, iss1, iss2, ir, ig, inl, jnl
|
|
real(8) fi, fip, dd
|
|
complex(8) fp,fm,ci
|
|
real(8) af(nhsa), aa(nhsa) ! automatic arrays
|
|
complex(8) dtemp(ngw) !
|
|
complex(8), allocatable :: psi(:)
|
|
!
|
|
!
|
|
call start_clock( 'dforce' )
|
|
!
|
|
allocate( psi( nnrsx ) )
|
|
!
|
|
! important: if n is odd => c(*,n+1)=0.
|
|
!
|
|
if (mod(n,2).ne.0.and.i.eq.n) then
|
|
do ig=1,ngw
|
|
ca(ig)=(0.,0.)
|
|
end do
|
|
endif
|
|
!
|
|
ci=(0.0,1.0)
|
|
!
|
|
if (.not.tbuff) then
|
|
!
|
|
psi (:) = (0.d0, 0.d0)
|
|
do ig=1,ngw
|
|
psi(nms(ig))=CONJG(c(ig)-ci*ca(ig))
|
|
psi(nps(ig))=c(ig)+ci*ca(ig)
|
|
end do
|
|
!
|
|
call ivfftw(psi,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
!
|
|
else
|
|
!
|
|
! read psi from buffer 21
|
|
!
|
|
#if defined(__CRAYY)
|
|
buffer in(21,0) (psi(1),psi(nnrsx))
|
|
ios = unit(21)
|
|
#else
|
|
read(21,iostat=ios) psi
|
|
#endif
|
|
if(ios.ne.0) call errore &
|
|
& (' dforce',' error in reading unit 21',ios)
|
|
!
|
|
endif
|
|
!
|
|
iss1=ispin(i)
|
|
!
|
|
! the following avoids a potential out-of-bounds error
|
|
!
|
|
if (i.ne.n) then
|
|
iss2=ispin(i+1)
|
|
else
|
|
iss2=iss1
|
|
end if
|
|
!
|
|
do ir=1,nnrsx
|
|
psi(ir)=CMPLX(v(ir,iss1)* DBLE(psi(ir)), v(ir,iss2)*AIMAG(psi(ir)) )
|
|
end do
|
|
!
|
|
call fwfftw(psi,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
!
|
|
! note : the factor 0.5 appears
|
|
! in the kinetic energy because it is defined as 0.5*g**2
|
|
! in the potential part because of the logics
|
|
!
|
|
|
|
if (tens) then
|
|
fi =-0.5
|
|
fip=-0.5
|
|
else
|
|
fi =- f(i)*0.5
|
|
fip=-f(i+1)*0.5
|
|
end if
|
|
|
|
do ig=1,ngw
|
|
fp= psi(nps(ig)) + psi(nms(ig))
|
|
fm= psi(nps(ig)) - psi(nms(ig))
|
|
df(ig)= fi*(tpiba2*ggp(ig)* c(ig)+CMPLX(DBLE(fp), AIMAG(fm)))
|
|
da(ig)=fip*(tpiba2*ggp(ig)*ca(ig)+CMPLX(AIMAG(fp),-DBLE(fm)))
|
|
end do
|
|
|
|
if(ismeta) call dforce_meta(c,ca,df,da,psi,iss1,iss2,fi,fip) !METAGGA
|
|
!
|
|
! aa_i,i,n = sum_j d_i,ij <beta_i,j|c_n>
|
|
!
|
|
if(nhsa.gt.0)then
|
|
do inl=1,nhsa
|
|
af(inl)=0.
|
|
aa(inl)=0.
|
|
end do
|
|
!
|
|
do is=1,nsp
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
isa=0
|
|
do ism=1,is-1
|
|
isa=isa+na(ism)
|
|
end do
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
isa=isa+1
|
|
dd = deeq(iv,jv,isa,iss1)+dvan(iv,jv,is)
|
|
if(tens) then
|
|
af(inl)=af(inl)-dd*bec(jnl, i)
|
|
else
|
|
af(inl)=af(inl)- f(i)*dd*bec(jnl, i)
|
|
end if
|
|
dd = deeq(iv,jv,isa,iss2)+dvan(iv,jv,is)
|
|
if(tens) then
|
|
if (i.ne.n) aa(inl)=aa(inl)-dd*bec(jnl,i+1)
|
|
else
|
|
if (i.ne.n) aa(inl)=aa(inl)-f(i+1)*dd*bec(jnl,i+1)
|
|
end if
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
do ig=1,ngw
|
|
dtemp(ig)=(0.,0.)
|
|
end do
|
|
call MXMA &
|
|
& (betae,1,2*ngw,af,1,nhsa,dtemp,1,2*ngw,2*ngw,nhsa,1)
|
|
do ig=1,ngw
|
|
df(ig)=df(ig)+dtemp(ig)
|
|
end do
|
|
!
|
|
do ig=1,ngw
|
|
dtemp(ig)=(0.,0.)
|
|
end do
|
|
call MXMA &
|
|
& (betae,1,2*ngw,aa,1,nhsa,dtemp,1,2*ngw,2*ngw,nhsa,1)
|
|
do ig=1,ngw
|
|
da(ig)=da(ig)+dtemp(ig)
|
|
end do
|
|
endif
|
|
|
|
deallocate( psi )
|
|
!
|
|
call stop_clock( 'dforce' )
|
|
!
|
|
return
|
|
end subroutine dforce
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine dotcsc(eigr,cp)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
use ions_base, only: nas => nax, na, nsp, nat
|
|
use io_global, only: stdout
|
|
use gvecw, only: ngw
|
|
use electrons_base, only: n => nbsp
|
|
use reciprocal_vectors, only: gstart
|
|
use cvan, only: ish, nvb
|
|
use uspp, only: nhsa=>nkb, qq
|
|
use uspp_param, only: nh
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
!
|
|
complex(8) eigr(ngw,nat), cp(ngw,n)
|
|
! local variables
|
|
real(8) rsum, csc(n) ! automatic array
|
|
complex(8) temp(ngw) ! automatic array
|
|
|
|
real(8), allocatable:: becp(:,:)
|
|
integer i,kmax,nnn,k,ig,is,ia,iv,jv,inl,jnl
|
|
!
|
|
allocate(becp(nhsa,n))
|
|
!
|
|
! < beta | phi > is real. only the i lowest:
|
|
!
|
|
nnn=min(12,n)
|
|
do i=nnn,1,-1
|
|
kmax=i
|
|
call nlsm1(i,1,nvb,eigr,cp,becp)
|
|
!
|
|
do k=1,kmax
|
|
do ig=1,ngw
|
|
temp(ig)=CONJG(cp(ig,k))*cp(ig,i)
|
|
end do
|
|
csc(k)=2.*DBLE(SUM(temp))
|
|
if (gstart == 2) csc(k)=csc(k)-DBLE(temp(1))
|
|
end do
|
|
|
|
call mp_sum( csc( 1:kmax ) )
|
|
|
|
do k=1,kmax
|
|
rsum=0.
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
rsum = rsum + &
|
|
& qq(iv,jv,is)*becp(inl,i)*becp(jnl,k)
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
csc(k)=csc(k)+rsum
|
|
end do
|
|
!
|
|
WRITE( stdout,'(a,12f18.15)')' dotcsc = ',(csc(k),k=1,i)
|
|
!
|
|
end do
|
|
WRITE( stdout,*)
|
|
!
|
|
deallocate(becp)
|
|
!
|
|
return
|
|
end subroutine dotcsc
|
|
!-----------------------------------------------------------------------
|
|
subroutine drhov(irb,eigrb,rhovan,rhog,rhor)
|
|
!-----------------------------------------------------------------------
|
|
! this routine calculates arrays drhog drhor, derivatives wrt h of:
|
|
!
|
|
! n_v(g) = sum_i,ij rho_i,ij q_i,ji(g) e^-ig.r_i
|
|
!
|
|
! Same logic as in routine rhov.
|
|
! On input rhor and rhog must contain the smooth part only !!!
|
|
! Output in module derho (drhor, drhog)
|
|
!
|
|
use kinds, only: dp
|
|
use control_flags, only: iprint
|
|
use parameters, only: natx, nsx
|
|
use ions_base, only: na, nsp, nat, nas => nax
|
|
use cvan
|
|
use uspp_param, only: nhm, nh
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nr3x, nnr => nnrx
|
|
use electrons_base, only: nspin
|
|
use gvecb
|
|
use gvecp, only: ng => ngm
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nr3bx, nnrb => nnrbx
|
|
use cell_base, only: ainv
|
|
use qgb_mod
|
|
use para_mod
|
|
use cdvan
|
|
use derho
|
|
use dqgb_mod
|
|
use recvecs_indexes, only: nm, np
|
|
|
|
implicit none
|
|
! input
|
|
integer, intent(in) :: irb(3,nat)
|
|
real(8), intent(in):: rhor(nnr,nspin)
|
|
real(8) :: rhovan(nhm*(nhm+1)/2,nat,nspin)
|
|
complex(8), intent(in):: eigrb(ngb,nat), rhog(ng,nspin)
|
|
! local
|
|
integer i, j, isup, isdw, nfft, ifft, iv, jv, ig, ijv, is, iss, &
|
|
& isa, ia, ir, irb3, imin3, imax3
|
|
real(8) sum, dsum
|
|
complex(8) fp, fm, ci
|
|
complex(8), allocatable :: v(:)
|
|
complex(8), allocatable:: dqgbt(:,:)
|
|
complex(8), allocatable :: qv(:)
|
|
!
|
|
!
|
|
do j=1,3
|
|
do i=1,3
|
|
do iss=1,nspin
|
|
do ir=1,nnr
|
|
drhor(ir,iss,i,j)=-rhor(ir,iss)*ainv(j,i)
|
|
end do
|
|
do ig=1,ng
|
|
drhog(ig,iss,i,j)=-rhog(ig,iss)*ainv(j,i)
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
if (nvb.eq.0) return
|
|
!
|
|
allocate( v( nnr ) )
|
|
allocate( qv( nnrb ) )
|
|
allocate( dqgbt( ngb, 2 ) )
|
|
|
|
ci=(0.,1.)
|
|
!
|
|
if(nspin.eq.1) then
|
|
! ------------------------------------------------------------------
|
|
! nspin=1 : two fft at a time, one per atom, if possible
|
|
! ------------------------------------------------------------------
|
|
do i=1,3
|
|
do j=1,3
|
|
!
|
|
v(:) = (0.d0, 0.d0)
|
|
!
|
|
iss=1
|
|
isa=1
|
|
do is=1,nvb
|
|
#ifdef __PARA
|
|
do ia=1,na(is)
|
|
nfft=1
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 15
|
|
#else
|
|
do ia=1,na(is),2
|
|
nfft=2
|
|
#endif
|
|
dqgbt(:,:) = (0.d0, 0.d0)
|
|
if (ia.eq.na(is)) nfft=1
|
|
!
|
|
! nfft=2 if two ffts at the same time are performed
|
|
!
|
|
do ifft=1,nfft
|
|
ijv=0
|
|
do iv=1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
sum = rhovan(ijv,isa+ifft-1,iss)
|
|
dsum=drhovan(ijv,isa+ifft-1,iss,i,j)
|
|
if(iv.ne.jv) then
|
|
sum =2.*sum
|
|
dsum=2.*dsum
|
|
endif
|
|
do ig=1,ngb
|
|
dqgbt(ig,ifft)=dqgbt(ig,ifft) + &
|
|
& (sum*dqgb(ig,ijv,is,i,j) + &
|
|
& dsum*qgb(ig,ijv,is) )
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
! add structure factor
|
|
!
|
|
qv(:) = (0.d0, 0.d0)
|
|
if(nfft.eq.2) then
|
|
do ig=1,ngb
|
|
qv(npb(ig)) = eigrb(ig,isa )*dqgbt(ig,1) &
|
|
& + ci* eigrb(ig,isa+1 )*dqgbt(ig,2)
|
|
qv(nmb(ig))= &
|
|
& CONJG(eigrb(ig,isa )*dqgbt(ig,1)) &
|
|
& + ci*CONJG(eigrb(ig,isa+1)*dqgbt(ig,2))
|
|
end do
|
|
else
|
|
do ig=1,ngb
|
|
qv(npb(ig)) = eigrb(ig,isa)*dqgbt(ig,1)
|
|
qv(nmb(ig)) = &
|
|
& CONJG(eigrb(ig,isa)*dqgbt(ig,1))
|
|
end do
|
|
endif
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
! qv = US contribution in real space on box grid
|
|
! for atomic species is, real(qv)=atom ia, imag(qv)=atom ia+1
|
|
!
|
|
! add qv(r) to v(r), in real space on the dense grid
|
|
!
|
|
call box2grid(irb(1,isa),1,qv,v)
|
|
if (nfft.eq.2) call box2grid(irb(1,isa+1),2,qv,v)
|
|
15 isa=isa+nfft
|
|
!
|
|
end do
|
|
end do
|
|
!
|
|
do ir=1,nnr
|
|
drhor(ir,iss,i,j)=drhor(ir,iss,i,j)+DBLE(v(ir))
|
|
end do
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ig=1,ng
|
|
drhog(ig,iss,i,j)=drhog(ig,iss,i,j)+v(np(ig))
|
|
end do
|
|
!
|
|
enddo
|
|
enddo
|
|
!
|
|
else
|
|
! ------------------------------------------------------------------
|
|
! nspin=2: two fft at a time, one for spin up and one for spin down
|
|
! ------------------------------------------------------------------
|
|
isup=1
|
|
isdw=2
|
|
do i=1,3
|
|
do j=1,3
|
|
v(:) = (0.d0, 0.d0)
|
|
isa=1
|
|
do is=1,nvb
|
|
do ia=1,na(is)
|
|
#ifdef __PARA
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 25
|
|
#endif
|
|
do iss=1,2
|
|
dqgbt(:,iss) = (0.d0, 0.d0)
|
|
ijv=0
|
|
do iv= 1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
sum=rhovan(ijv,isa,iss)
|
|
dsum =drhovan(ijv,isa,iss,i,j)
|
|
if(iv.ne.jv) then
|
|
sum =2.*sum
|
|
dsum=2.*dsum
|
|
endif
|
|
do ig=1,ngb
|
|
dqgbt(ig,iss)=dqgbt(ig,iss) + &
|
|
& (sum*dqgb(ig,ijv,is,i,j) + &
|
|
& dsum*qgb(ig,ijv,is))
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
! add structure factor
|
|
!
|
|
qv(:) = (0.d0, 0.d0)
|
|
do ig=1,ngb
|
|
qv(npb(ig))= eigrb(ig,isa)*dqgbt(ig,1) &
|
|
& + ci* eigrb(ig,isa)*dqgbt(ig,2)
|
|
qv(nmb(ig))= CONJG(eigrb(ig,isa)*dqgbt(ig,1)) &
|
|
& + ci*CONJG(eigrb(ig,isa)*dqgbt(ig,2))
|
|
end do
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
! qv is the now the US augmentation charge for atomic species is
|
|
! and atom ia: real(qv)=spin up, imag(qv)=spin down
|
|
!
|
|
! add qv(r) to v(r), in real space on the dense grid
|
|
!
|
|
call box2grid2(irb(1,isa),qv,v)
|
|
25 isa=isa+1
|
|
end do
|
|
end do
|
|
!
|
|
do ir=1,nnr
|
|
drhor(ir,isup,i,j) = drhor(ir,isup,i,j) + DBLE(v(ir))
|
|
drhor(ir,isdw,i,j) = drhor(ir,isdw,i,j) +AIMAG(v(ir))
|
|
enddo
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ig=1,ng
|
|
fp=v(np(ig))+v(nm(ig))
|
|
fm=v(np(ig))-v(nm(ig))
|
|
drhog(ig,isup,i,j) = drhog(ig,isup,i,j) + &
|
|
& 0.5*CMPLX( DBLE(fp),AIMAG(fm))
|
|
drhog(ig,isdw,i,j) = drhog(ig,isdw,i,j) + &
|
|
& 0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
!
|
|
end do
|
|
end do
|
|
endif
|
|
deallocate(dqgbt)
|
|
deallocate( v )
|
|
deallocate( qv )
|
|
!
|
|
return
|
|
end subroutine drhov
|
|
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
real(8) function enkin(c)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! calculation of kinetic energy term
|
|
!
|
|
use constants, only: pi, fpi
|
|
use electrons_base, only: nx => nbspx, n => nbsp, f
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use gvecw, only: ggp
|
|
use mp, only: mp_sum
|
|
use cell_base, only: tpiba2
|
|
|
|
implicit none
|
|
! input
|
|
complex(8) c(ngw,nx)
|
|
! local
|
|
integer ig, i
|
|
real(8) sk(n) ! automatic array
|
|
!
|
|
!
|
|
do i=1,n
|
|
sk(i)=0.0
|
|
do ig=gstart,ngw
|
|
sk(i)=sk(i)+DBLE(CONJG(c(ig,i))*c(ig,i))*ggp(ig)
|
|
end do
|
|
end do
|
|
|
|
call mp_sum( sk(1:n) )
|
|
|
|
enkin=0.0
|
|
do i=1,n
|
|
enkin=enkin+f(i)*sk(i)
|
|
end do
|
|
enkin=enkin*tpiba2
|
|
!
|
|
return
|
|
end function enkin
|
|
!
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine force_ion(tau0,esr,fion,dsr)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! forces on ions, ionic term in real space (also stress if requested)
|
|
!
|
|
use parameters, only: nsx, natx
|
|
use control_flags, only: iprint, tpre
|
|
use constants, only: pi, fpi
|
|
use cell_base, only: ainv, a1, a2, a3
|
|
use ions_base, only: nsp, na, rcmax, zv
|
|
implicit none
|
|
! input
|
|
real(8) tau0(3,natx)
|
|
! output
|
|
real(8) fion(3,natx), dsr(3,3), esr
|
|
! local variables
|
|
integer i,j,k,l,m, ii, lax, inf, isak, isaj
|
|
real(8) rlm(3), rckj, rlmn, arg, addesr, addpre, repand, fxx
|
|
real(8), external :: erfc
|
|
!
|
|
!
|
|
esr=0.d0
|
|
if(tpre) dsr=0.d0
|
|
!
|
|
isak = 0
|
|
do k=1,nsp
|
|
isaj = 0
|
|
do j = 1, k-1
|
|
isaj = isaj + na(j)
|
|
end do
|
|
do j=k,nsp
|
|
rckj=sqrt(rcmax(k)**2+rcmax(j)**2)
|
|
lax=na(k)
|
|
if(k.eq.j) lax=lax-1
|
|
!
|
|
do l=1,lax
|
|
inf=1
|
|
if(k.eq.j) inf=l+1
|
|
!
|
|
do m=inf,na(j)
|
|
rlm(1) = tau0(1,l + isak) - tau0(1,m + isaj)
|
|
rlm(2) = tau0(2,l + isak) - tau0(2,m + isaj)
|
|
rlm(3) = tau0(3,l + isak) - tau0(3,m + isaj)
|
|
call pbc(rlm,a1,a2,a3,ainv,rlm)
|
|
!
|
|
rlmn=sqrt(rlm(1)**2+rlm(2)**2+rlm(3)**2)
|
|
!
|
|
arg=rlmn/rckj
|
|
addesr=zv(k)*zv(j)*erfc(arg)/rlmn
|
|
esr=esr+addesr
|
|
addpre=2.d0*zv(k)*zv(j)*exp(-arg*arg)/rckj/sqrt(pi)
|
|
repand=(addesr+addpre)/rlmn/rlmn
|
|
!
|
|
do i=1,3
|
|
fxx=repand*rlm(i)
|
|
fion(i,l+isak)=fion(i,l+isak)+fxx
|
|
fion(i,m+isaj)=fion(i,m+isaj)-fxx
|
|
if(tpre)then
|
|
do ii=1,3
|
|
dsr(i,ii)=dsr(i,ii)- &
|
|
& repand*rlm(i)*rlm(1)*ainv(ii,1)- &
|
|
& repand*rlm(i)*rlm(2)*ainv(ii,2)- &
|
|
& repand*rlm(i)*rlm(3)*ainv(ii,3)
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
isaj = isaj + na(j)
|
|
end do
|
|
isak = isak + na(k)
|
|
end do
|
|
|
|
return
|
|
end subroutine force_ion
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine force_ps(rhotemp,rhog,vtemp,ei1,ei2,ei3,fion1)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! Contribution to ionic forces from local pseudopotential
|
|
!
|
|
use kinds, only: dp
|
|
use constants, only: pi, fpi
|
|
use electrons_base, only: nspin
|
|
use gvecs
|
|
use gvecp, only: ng => ngm
|
|
use reciprocal_vectors, only: gstart, gx, mill_l, g
|
|
use cell_base, only: omega, tpiba, tpiba2
|
|
use ions_base, only: nsp, na, nas => nax, nat
|
|
use grid_dimensions, only: nr1, nr2, nr3
|
|
use parameters, only: nsx, natx
|
|
use local_pseudo, only: vps, rhops
|
|
!
|
|
implicit none
|
|
! input
|
|
complex(8) rhotemp(ng), rhog(ng,nspin), vtemp(ng), &
|
|
& ei1(-nr1:nr1,nat), &
|
|
& ei2(-nr2:nr2,nat), &
|
|
& ei3(-nr3:nr3,nat)
|
|
! output
|
|
real(8) fion1(3,natx)
|
|
! local
|
|
integer ig, is, isa, ism, ia, ix, iss, isup, isdw
|
|
integer i, j, k
|
|
real(8) wz
|
|
complex(8) eigrx, vcgs, cnvg, cvn
|
|
!
|
|
! wz = factor for g.neq.0 because of c*(g)=c(-g)
|
|
!
|
|
wz=2.0
|
|
do is=1,nsp
|
|
isa=0
|
|
do ism=1,is-1
|
|
isa=isa+na(ism)
|
|
end do
|
|
do ia=1,na(is)
|
|
isa=isa+1
|
|
do ix=1,3
|
|
if(nspin.eq.1)then
|
|
iss=1
|
|
if (gstart == 2) vtemp(1)=0.0
|
|
do ig=gstart,ngs
|
|
vcgs=CONJG(rhotemp(ig))*fpi/(tpiba2*g(ig))
|
|
cnvg=rhops(ig,is)*vcgs
|
|
cvn=vps(ig,is)*CONJG(rhog(ig,iss))
|
|
i = mill_l(1,ig)
|
|
j = mill_l(2,ig)
|
|
k = mill_l(3,ig)
|
|
eigrx=ei1(i,isa)*ei2(j,isa)*ei3(k,isa)
|
|
vtemp(ig)=eigrx*(cnvg+cvn)*CMPLX(0.d0,gx(ix,ig))
|
|
end do
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
if (gstart == 2) vtemp(1)=0.0
|
|
do ig=gstart,ngs
|
|
vcgs=CONJG(rhotemp(ig))*fpi/(tpiba2*g(ig))
|
|
cnvg=rhops(ig,is)*vcgs
|
|
cvn=vps(ig,is)*CONJG(rhog(ig,isup) &
|
|
& +rhog(ig,isdw))
|
|
i = mill_l(1,ig)
|
|
j = mill_l(2,ig)
|
|
k = mill_l(3,ig)
|
|
eigrx=ei1(i,isa)*ei2(j,isa)*ei3(k,isa)
|
|
vtemp(ig)=eigrx*(cnvg+cvn)*CMPLX(0.d0,gx(ix,ig))
|
|
end do
|
|
endif
|
|
fion1(ix,isa) = fion1(ix,isa) + tpiba*omega* wz*DBLE(SUM(vtemp))
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
return
|
|
end subroutine force_ps
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine gausin(eigr,cm)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! initialize wavefunctions with gaussians - edit to fit your system
|
|
!
|
|
use ions_base, only: nas => nax, na, nsp, nat
|
|
use electrons_base, only: n => nbsp
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gx, g
|
|
!
|
|
implicit none
|
|
!
|
|
complex(8) eigr(ngw,nat), cm(ngw,n)
|
|
real(8) sigma, auxf
|
|
integer nband, is, ia, ig, isa
|
|
!
|
|
sigma=12.0
|
|
nband=0
|
|
!!! do is=1,nsp
|
|
isa = 0
|
|
is=1
|
|
do ia=1,na(is)
|
|
! s-like gaussians
|
|
nband=nband+1
|
|
do ig=1,ngw
|
|
auxf=exp(-g(ig)/sigma**2)
|
|
cm(ig,nband)=auxf*eigr(ig,ia+isa)
|
|
end do
|
|
! px-like gaussians
|
|
nband=nband+1
|
|
do ig=1,ngw
|
|
auxf=exp(-g(ig)/sigma**2)
|
|
cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(1,ig)
|
|
end do
|
|
! py-like gaussians
|
|
nband=nband+1
|
|
do ig=1,ngw
|
|
auxf=exp(-g(ig)/sigma**2)
|
|
cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(2,ig)
|
|
end do
|
|
! pz-like gaussians
|
|
nband=nband+1
|
|
do ig=1,ngw
|
|
auxf=exp(-g(ig)/sigma**2)
|
|
cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(3,ig)
|
|
end do
|
|
end do
|
|
isa = isa + na(is)
|
|
is=2
|
|
do ia=1,na(is)
|
|
! s-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)
|
|
! end do
|
|
! px-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(1,ig)
|
|
! end do
|
|
! py-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(2,ig)
|
|
! end do
|
|
! pz-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(3,ig)
|
|
! end do
|
|
! dxy-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(1,ig)*gx(2,ig)
|
|
! end do
|
|
! dxz-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(1,ig)*gx(3,ig)
|
|
! end do
|
|
! dxy-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)*gx(2,ig)*gx(3,ig)
|
|
! end do
|
|
! dx2-y2-like gaussians
|
|
! nband=nband+1
|
|
! do ig=1,ngw
|
|
! auxf=exp(-g(ig)/sigma**2)
|
|
! cm(ig,nband)=auxf*eigr(ig,ia+isa)* &
|
|
! & (gx(1,ig)**2-gx(2,ig)**2)
|
|
! end do
|
|
end do
|
|
!!! end do
|
|
return
|
|
end subroutine gausin
|
|
!
|
|
|
|
!-------------------------------------------------------------------------
|
|
subroutine gracsc(bec,betae,cp,i,csc)
|
|
!-----------------------------------------------------------------------
|
|
! requires in input the updated bec(k) for k<i
|
|
! on output: bec(i) is recalculated
|
|
!
|
|
use ions_base, only: na
|
|
use cvan, only :nvb, ish
|
|
use uspp, only :nhsa=>nkb, nhsavb=>nkbus, qq
|
|
use uspp_param, only: nh
|
|
use electrons_base, only: n => nbsp, ispin => fspin, nx => nbspx
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
!
|
|
integer i
|
|
complex(8) betae(ngw,nhsa)
|
|
real(8) bec(nhsa,n), cp(2,ngw,n)
|
|
real(8) csc(nx)
|
|
integer k, kmax,ig, is, iv, jv, ia, inl, jnl
|
|
real(8) rsum, temp(ngw) ! automatic array
|
|
!
|
|
! calculate csc(k)=<cp(i)|cp(k)>, k<i
|
|
!
|
|
kmax=i-1
|
|
do k=1,kmax
|
|
csc(k)=0.
|
|
if (ispin(i).eq.ispin(k)) then
|
|
do ig=1,ngw
|
|
temp(ig)=cp(1,ig,k)*cp(1,ig,i)+cp(2,ig,k)*cp(2,ig,i)
|
|
end do
|
|
csc(k)=2.*SUM(temp)
|
|
if (gstart == 2) csc(k)=csc(k)-temp(1)
|
|
endif
|
|
end do
|
|
|
|
call mp_sum( csc( 1:kmax ) )
|
|
|
|
!
|
|
! calculate bec(i)=<cp(i)|beta>
|
|
!
|
|
do inl=1,nhsavb
|
|
do ig=1,ngw
|
|
temp(ig)=cp(1,ig,i)* DBLE(betae(ig,inl))+ &
|
|
& cp(2,ig,i)*AIMAG(betae(ig,inl))
|
|
end do
|
|
bec(inl,i)=2.*SUM(temp)
|
|
if (gstart == 2) bec(inl,i)= bec(inl,i)-temp(1)
|
|
end do
|
|
|
|
call mp_sum( bec( 1:nhsavb, i ) )
|
|
!
|
|
! calculate csc(k)=<cp(i)|S|cp(k)>, k<i
|
|
!
|
|
do k=1,kmax
|
|
if (ispin(i).eq.ispin(k)) then
|
|
rsum=0.
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
rsum = rsum + qq(iv,jv,is)*bec(inl,i)*bec(jnl,k)
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
csc(k)=csc(k)+rsum
|
|
endif
|
|
end do
|
|
!
|
|
! orthogonalized cp(i) : |cp(i)>=|cp(i)>-\sum_k<i csc(k)|cp(k)>
|
|
!
|
|
! corresponing bec: bec(i)=<cp(i)|beta>-csc(k)<cp(k)|beta>
|
|
!
|
|
do k=1,kmax
|
|
do inl=1,nhsavb
|
|
bec(inl,i)=bec(inl,i)-csc(k)*bec(inl,k)
|
|
end do
|
|
end do
|
|
!
|
|
return
|
|
end subroutine gracsc
|
|
!-------------------------------------------------------------------------
|
|
subroutine gram(betae,bec,cp)
|
|
!-----------------------------------------------------------------------
|
|
! gram-schmidt orthogonalization of the set of wavefunctions cp
|
|
!
|
|
use uspp, only :nhsa=>nkb, nhsavb=> nkbus
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use gvecw, only: ngw
|
|
!
|
|
implicit none
|
|
!
|
|
real(8) bec(nhsa,n)
|
|
complex(8) cp(ngw,n), betae(ngw,nhsa)
|
|
!
|
|
real(8) :: anorm, cscnorm
|
|
real(8), allocatable :: csc( : )
|
|
integer :: i,k
|
|
external cscnorm
|
|
!
|
|
call start_clock( 'gram' )
|
|
|
|
allocate( csc( nx ) )
|
|
!
|
|
do i=1,n
|
|
call gracsc(bec,betae,cp,i,csc)
|
|
!
|
|
! calculate orthogonalized cp(i) : |cp(i)>=|cp(i)>-\sum_k<i csc(k)|cp(k)>
|
|
!
|
|
do k=1,i-1
|
|
call DAXPY(2*ngw,-csc(k),cp(1,k),1,cp(1,i),1)
|
|
end do
|
|
anorm =cscnorm(bec,cp,i)
|
|
call DSCAL(2*ngw,1.0/anorm,cp(1,i),1)
|
|
!
|
|
! these are the final bec's
|
|
!
|
|
call DSCAL(nhsavb,1.0/anorm,bec(1,i),1)
|
|
end do
|
|
!
|
|
deallocate( csc )
|
|
|
|
call stop_clock( 'gram' )
|
|
!
|
|
return
|
|
end subroutine gram
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine herman_skillman_grid(mesh,z,cmesh,r)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
implicit none
|
|
!
|
|
integer mesh
|
|
real(8) z, cmesh, r(mesh)
|
|
!
|
|
real(8) deltax
|
|
integer nblock,i,j,k
|
|
!
|
|
nblock = mesh/40
|
|
i=1
|
|
r(i)=0.0
|
|
cmesh=0.88534138/z**(1.0/3.0)
|
|
deltax=0.0025*cmesh
|
|
do j=1,nblock
|
|
do k=1,40
|
|
i=i+1
|
|
r(i)=r(i-1)+deltax
|
|
end do
|
|
deltax=deltax+deltax
|
|
end do
|
|
!
|
|
return
|
|
end subroutine herman_skillman_grid
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine herman_skillman_int(mesh,cmesh,func,asum)
|
|
!-----------------------------------------------------------------------
|
|
! simpsons rule integration for herman skillman mesh
|
|
! mesh - # of mesh points
|
|
! c - 0.8853418/z**(1/3.)
|
|
!
|
|
implicit none
|
|
integer mesh
|
|
real(8) cmesh, func(mesh), asum
|
|
!
|
|
integer i, j, k, i1, nblock
|
|
real(8) a1, a2e, a2o, a2es, h
|
|
!
|
|
a1=0.0
|
|
a2e=0.0
|
|
asum=0.0
|
|
h=0.0025*cmesh
|
|
nblock=mesh/40
|
|
i=1
|
|
func(1)=0.0
|
|
do j=1,nblock
|
|
do k=1,20
|
|
i=i+2
|
|
i1=i-1
|
|
a2es=a2e
|
|
a2o=func(i1)/12.0
|
|
a2e=func(i)/12.0
|
|
a1=a1+5.0*a2es+8.0*a2o-a2e
|
|
func(i1)=asum+a1*h
|
|
a1=a1-a2es+8.0*a2o+5.0*a2e
|
|
func(i)=asum+a1*h
|
|
end do
|
|
asum=func(i)
|
|
a1=0.0
|
|
h=h+h
|
|
end do
|
|
!
|
|
return
|
|
end subroutine herman_skillman_int
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine initbox ( tau0, taub, irb )
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! sets the indexes irb and positions taub for the small boxes
|
|
! around atoms
|
|
!
|
|
use parameters, only: natx, nsx
|
|
use ions_base, only: nsp, na, nat
|
|
use grid_dimensions, only: nr1, nr2, nr3
|
|
use cell_base, only: ainv, a1, a2, a3
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b
|
|
use control_flags, only: iprsta
|
|
use cvan, only: nvb
|
|
use io_global, only: stdout
|
|
|
|
implicit none
|
|
! input
|
|
real(8), intent(in):: tau0(3,natx)
|
|
! output
|
|
integer, intent(out):: irb(3,nat)
|
|
real(8), intent(out):: taub(3,natx)
|
|
! local
|
|
real(8) x(3), xmod
|
|
integer nr(3), nrb(3), xint, is, ia, i, isa
|
|
!
|
|
nr (1)=nr1
|
|
nr (2)=nr2
|
|
nr (3)=nr3
|
|
nrb(1)=nr1b
|
|
nrb(2)=nr2b
|
|
nrb(3)=nr3b
|
|
!
|
|
isa = 0
|
|
do is=1,nsp
|
|
do ia=1,na(is)
|
|
isa = isa + 1
|
|
!
|
|
do i=1,3
|
|
!
|
|
! bring atomic positions to crystal axis
|
|
!
|
|
x(i) = ainv(i,1)*tau0(1,isa) + &
|
|
& ainv(i,2)*tau0(2,isa) + &
|
|
& ainv(i,3)*tau0(3,isa)
|
|
!
|
|
! bring x in the range between 0 and 1
|
|
!
|
|
x(i) = mod(x(i),1.d0)
|
|
if (x(i).lt.0.d0) x(i)=x(i)+1.d0
|
|
!
|
|
! case of nrb(i) even
|
|
!
|
|
if (mod(nrb(i),2).eq.0) then
|
|
!
|
|
! find irb = index of the grid point at the corner of the small box
|
|
! (the indices of the small box run from irb to irb+nrb-1)
|
|
!
|
|
xint=int(x(i)*nr(i))
|
|
irb (i,isa)=xint+1-nrb(i)/2+1
|
|
if(irb(i,isa).lt.1) irb(i,isa)=irb(i,isa)+nr(i)
|
|
!
|
|
! x(i) are the atomic positions in crystal coordinates, where the
|
|
! "crystal lattice" is the small box lattice and the origin is at
|
|
! the corner of the small box. Used to calculate phases exp(iG*taub)
|
|
!
|
|
xmod=x(i)*nr(i)-xint
|
|
x(i)=(xmod+nrb(i)/2-1)/nr(i)
|
|
else
|
|
!
|
|
! case of nrb(i) odd - see above for comments
|
|
!
|
|
xint=nint(x(i)*nr(i))
|
|
irb (i,isa)=xint+1-(nrb(i)-1)/2
|
|
if(irb(i,isa).lt.1) irb(i,isa)=irb(i,isa)+nr(i)
|
|
xmod=x(i)*nr(i)-xint
|
|
x(i)=(xmod+(nrb(i)-1)/2)/nr(i)
|
|
end if
|
|
end do
|
|
!
|
|
! bring back taub in cartesian coordinates
|
|
!
|
|
do i=1,3
|
|
taub(i,isa)= x(1)*a1(i) + x(2)*a2(i) + x(3)*a3(i)
|
|
end do
|
|
end do
|
|
end do
|
|
|
|
if( iprsta > 2 ) then
|
|
isa = 1
|
|
do is=1,nvb
|
|
WRITE( stdout,'(/,2x,''species= '',i2)') is
|
|
do ia=1,na(is)
|
|
WRITE( stdout,2000) ia, (irb(i,isa),i=1,3)
|
|
2000 format(2x,'atom= ',i3,' irb1= ',i3,' irb2= ',i3,' irb3= ',i3)
|
|
isa = isa + 1
|
|
end do
|
|
end do
|
|
endif
|
|
|
|
!
|
|
return
|
|
end subroutine initbox
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine newd(vr,irb,eigrb,rhovan,fion)
|
|
!-----------------------------------------------------------------------
|
|
! this routine calculates array deeq:
|
|
! deeq_i,lm = \int V_eff(r) q_i,lm(r) dr
|
|
! and the corresponding term in forces
|
|
! fion_i = \int V_eff(r) \sum_lm rho_lm (dq_i,lm(r)/dR_i) dr
|
|
! where
|
|
! rho_lm = \sum_j f_j <psi_j|beta_l><beta_m|psi_j>
|
|
!
|
|
use kinds, only: dp
|
|
use uspp_param, only: nh, nhm
|
|
use uspp, only: deeq
|
|
use cvan, only: nvb
|
|
use ions_base, only: nas => nax, nat, nsp, na
|
|
use parameters, only: natx, nsx
|
|
use constants, only: pi, fpi
|
|
use grid_dimensions, only: nr3, nnr => nnrx
|
|
use gvecb
|
|
use small_box, only: omegab, tpibab
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nr3bx, nnrb => nnrbx
|
|
use qgb_mod
|
|
use electrons_base, only: nspin
|
|
use control_flags, only: iprint, thdyn, tfor, tprnfor
|
|
use para_mod
|
|
use mp, only: mp_sum
|
|
!
|
|
implicit none
|
|
! input
|
|
integer irb(3,nat)
|
|
real(8) rhovan(nhm*(nhm+1)/2,nat,nspin)
|
|
complex(8) eigrb(ngb,nat)
|
|
real(8) vr(nnr,nspin)
|
|
! output
|
|
real(8) fion(3,natx)
|
|
! local
|
|
integer isup,isdw,iss, iv,ijv,jv, ik, nfft, isa, ia, is, ig
|
|
integer irb3, imin3, imax3
|
|
real(8) fvan(3,natx,nsx), fac, fac1, fac2, boxdotgrid
|
|
complex(8) ci, facg1, facg2
|
|
complex(8), allocatable :: qv(:)
|
|
external boxdotgrid
|
|
!
|
|
call start_clock( 'newd' )
|
|
ci=(0.d0,1.d0)
|
|
fac=omegab/DBLE(nr1b*nr2b*nr3b)
|
|
deeq (:,:,:,:) = 0.d0
|
|
fvan (:,:,:) = 0.d0
|
|
|
|
allocate( qv( nnrb ) )
|
|
!
|
|
! calculation of deeq_i,lm = \int V_eff(r) q_i,lm(r) dr
|
|
!
|
|
isa=1
|
|
do is=1,nvb
|
|
#ifdef __PARA
|
|
do ia=1,na(is)
|
|
nfft=1
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 15
|
|
#else
|
|
do ia=1,na(is),2
|
|
nfft=2
|
|
#endif
|
|
if(ia.eq.na(is)) nfft=1
|
|
!
|
|
! two ffts at the same time, on two atoms (if possible: nfft=2)
|
|
!
|
|
ijv=0
|
|
do iv=1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
qv(:) = (0.d0, 0.d0)
|
|
if (nfft.eq.2) then
|
|
do ig=1,ngb
|
|
qv(npb(ig))= eigrb(ig,isa )*qgb(ig,ijv,is) &
|
|
& + ci*eigrb(ig,isa+1)*qgb(ig,ijv,is)
|
|
qv(nmb(ig))= CONJG( &
|
|
& eigrb(ig,isa )*qgb(ig,ijv,is)) &
|
|
& + ci*CONJG( &
|
|
& eigrb(ig,isa+1)*qgb(ig,ijv,is))
|
|
end do
|
|
else
|
|
do ig=1,ngb
|
|
qv(npb(ig)) = eigrb(ig,isa)*qgb(ig,ijv,is)
|
|
qv(nmb(ig)) = CONJG( &
|
|
& eigrb(ig,isa)*qgb(ig,ijv,is))
|
|
end do
|
|
end if
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
do iss=1,nspin
|
|
deeq(iv,jv,isa,iss) = fac * &
|
|
& boxdotgrid(irb(1,isa),1,qv,vr(1,iss))
|
|
if (iv.ne.jv) &
|
|
& deeq(jv,iv,isa,iss)=deeq(iv,jv,isa,iss)
|
|
!
|
|
if (nfft.eq.2) then
|
|
deeq(iv,jv,isa+1,iss) = fac* &
|
|
& boxdotgrid(irb(1,isa+1),2,qv,vr(1,iss))
|
|
if (iv.ne.jv) &
|
|
& deeq(jv,iv,isa+1,iss)=deeq(iv,jv,isa+1,iss)
|
|
end if
|
|
end do
|
|
end do
|
|
end do
|
|
15 isa=isa+nfft
|
|
end do
|
|
end do
|
|
|
|
call reduce(nat*nhm*nhm*nspin,deeq)
|
|
|
|
if (.not.( tfor .or. thdyn .or. tprnfor ) ) go to 10
|
|
!
|
|
! calculation of fion_i = \int V_eff(r) \sum_lm rho_lm (dq_i,lm(r)/dR_i) dr
|
|
!
|
|
isa=1
|
|
if(nspin.eq.1) then
|
|
! =================================================================
|
|
! case nspin=1: two ffts at the same time, on two atoms (if possible)
|
|
! -----------------------------------------------------------------
|
|
iss=1
|
|
isa=1
|
|
do is=1,nvb
|
|
#ifdef __PARA
|
|
do ia=1,na(is)
|
|
nfft=1
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 20
|
|
#else
|
|
do ia=1,na(is),2
|
|
nfft=2
|
|
#endif
|
|
if( ia.eq.na(is)) nfft=1
|
|
do ik=1,3
|
|
qv(:) = (0.d0, 0.d0)
|
|
ijv=0
|
|
do iv=1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
if(iv.ne.jv) then
|
|
fac1=2.d0*fac*tpibab*rhovan(ijv,isa,iss)
|
|
if (nfft.eq.2) fac2=2.d0*fac*tpibab* &
|
|
& rhovan(ijv,isa+1,iss)
|
|
else
|
|
fac1= fac*tpibab*rhovan(ijv,isa,iss)
|
|
if (nfft.eq.2) fac2= fac*tpibab* &
|
|
& rhovan(ijv,isa+1,iss)
|
|
endif
|
|
if (nfft.eq.2) then
|
|
do ig=1,ngb
|
|
facg1 = CMPLX(0.d0,-gxb(ik,ig)) * &
|
|
& qgb(ig,ijv,is) * fac1
|
|
facg2 = CMPLX(0.d0,-gxb(ik,ig)) * &
|
|
& qgb(ig,ijv,is) * fac2
|
|
qv(npb(ig)) = qv(npb(ig)) &
|
|
& + eigrb(ig,isa )*facg1 &
|
|
& + ci*eigrb(ig,isa+1)*facg2
|
|
qv(nmb(ig)) = qv(nmb(ig)) &
|
|
& + CONJG(eigrb(ig,isa )*facg1)&
|
|
& +ci*CONJG(eigrb(ig,isa+1)*facg2)
|
|
end do
|
|
else
|
|
do ig=1,ngb
|
|
facg1 = CMPLX(0.d0,-gxb(ik,ig)) * &
|
|
& qgb(ig,ijv,is)*fac1
|
|
qv(npb(ig)) = qv(npb(ig)) &
|
|
& + eigrb(ig,isa)*facg1
|
|
qv(nmb(ig)) = qv(nmb(ig)) &
|
|
& + CONJG( eigrb(ig,isa)*facg1)
|
|
end do
|
|
end if
|
|
end do
|
|
end do
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
fvan(ik,ia,is) = &
|
|
& boxdotgrid(irb(1,isa),1,qv,vr(1,iss))
|
|
!
|
|
if (nfft.eq.2) fvan(ik,ia+1,is) = &
|
|
& boxdotgrid(irb(1,isa+1),2,qv,vr(1,iss))
|
|
end do
|
|
20 isa = isa+nfft
|
|
end do
|
|
end do
|
|
else
|
|
! =================================================================
|
|
! case nspin=2: up and down spin fft's combined into a single fft
|
|
! -----------------------------------------------------------------
|
|
isup=1
|
|
isdw=2
|
|
isa=1
|
|
do is=1,nvb
|
|
do ia=1,na(is)
|
|
#ifdef __PARA
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 25
|
|
#endif
|
|
do ik=1,3
|
|
qv(:) = (0.d0, 0.d0)
|
|
ijv=0
|
|
!
|
|
do iv=1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
if(iv.ne.jv) then
|
|
fac1=2.d0*fac*tpibab*rhovan(ijv,isa,isup)
|
|
fac2=2.d0*fac*tpibab*rhovan(ijv,isa,isdw)
|
|
else
|
|
fac1= fac*tpibab*rhovan(ijv,isa,isup)
|
|
fac2= fac*tpibab*rhovan(ijv,isa,isdw)
|
|
end if
|
|
do ig=1,ngb
|
|
facg1 = fac1 * CMPLX(0.d0,-gxb(ik,ig)) * &
|
|
& qgb(ig,ijv,is) * eigrb(ig,isa)
|
|
facg2 = fac2 * CMPLX(0.d0,-gxb(ik,ig)) * &
|
|
& qgb(ig,ijv,is) * eigrb(ig,isa)
|
|
qv(npb(ig)) = qv(npb(ig)) &
|
|
& + facg1 + ci*facg2
|
|
qv(nmb(ig)) = qv(nmb(ig)) &
|
|
& +CONJG(facg1)+ci*conjg(facg2)
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
fvan(ik,ia,is) = &
|
|
& boxdotgrid(irb(1,isa),isup,qv,vr(1,isup)) + &
|
|
& boxdotgrid(irb(1,isa),isdw,qv,vr(1,isdw))
|
|
end do
|
|
25 isa = isa+1
|
|
end do
|
|
end do
|
|
end if
|
|
|
|
call reduce(3*natx*nvb,fvan)
|
|
|
|
isa = 0
|
|
DO is = 1, nvb
|
|
DO ia = 1, na(is)
|
|
isa = isa + 1
|
|
fion(:,isa) = fion(:,isa) - fvan(:,ia,is)
|
|
END DO
|
|
END DO
|
|
|
|
deallocate( qv )
|
|
!
|
|
10 call stop_clock( 'newd' )
|
|
!
|
|
return
|
|
end subroutine newd
|
|
!-------------------------------------------------------------------------
|
|
subroutine nlfl(bec,becdr,lambda,fion)
|
|
!-----------------------------------------------------------------------
|
|
! contribution to fion due to the orthonormality constraint
|
|
!
|
|
!
|
|
use io_global, only: stdout
|
|
use ions_base, only: na, nsp
|
|
use parameters, only: natx
|
|
use uspp, only :nhsa=>nkb, qq
|
|
use uspp_param, only: nhm, nh
|
|
use cvan, only: ish, nvb
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use constants, only: pi, fpi
|
|
!
|
|
implicit none
|
|
real(8) bec(nhsa,n), becdr(nhsa,n,3), lambda(nx,nx)
|
|
real(8) fion(3,natx)
|
|
!
|
|
integer k, is, ia, iv, jv, i, j, inl, isa
|
|
real(8) temp(nx,nx), tmpbec(nhm,nx),tmpdr(nx,nhm) ! automatic arrays
|
|
!
|
|
call start_clock( 'nlfl' )
|
|
do k=1,3
|
|
isa = 0
|
|
do is=1,nvb
|
|
do ia=1,na(is)
|
|
isa = isa + 1
|
|
!
|
|
tmpbec = 0.d0
|
|
tmpdr = 0.d0
|
|
!
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
inl=ish(is)+(jv-1)*na(is)+ia
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do i=1,n
|
|
tmpbec(iv,i)=tmpbec(iv,i) &
|
|
& + qq(iv,jv,is)*bec(inl,i)
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
!
|
|
do iv=1,nh(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
do i=1,n
|
|
tmpdr(i,iv)=becdr(inl,i,k)
|
|
end do
|
|
end do
|
|
!
|
|
if(nh(is).gt.0)then
|
|
temp = 0.d0
|
|
!
|
|
call MXMA &
|
|
& (tmpdr,1,nx,tmpbec,1,nhm,temp,1,nx,n,nh(is),n)
|
|
!
|
|
do j=1,n
|
|
do i=1,n
|
|
temp(i,j)=temp(i,j)*lambda(i,j)
|
|
end do
|
|
end do
|
|
!
|
|
fion(k,isa)=fion(k,isa)+2.*SUM(temp)
|
|
endif
|
|
!
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
! end of x/y/z loop
|
|
!
|
|
call stop_clock( 'nlfl' )
|
|
return
|
|
end subroutine nlfl
|
|
|
|
|
|
!-----------------------------------------------------------------------
|
|
subroutine ortho &
|
|
& (eigr,cp,phi,x0,diff,iter,ccc,eps,max,delt,bephi,becp)
|
|
!-----------------------------------------------------------------------
|
|
! input = cp (non-orthonormal), beta
|
|
! input = phi |phi>=s'|c0>
|
|
! output= cp (orthonormal with s( r(t+dt) ) )
|
|
! output= bephi, becp
|
|
! the method used is similar to the version in les houches 1988
|
|
! 'simple molecular systems at..' p. 462-463 (18-22)
|
|
! xcx + b x + b^t x^t + a = 1
|
|
! where c = <s'c0|s|s'c0> b = <s'c0|s cp> a = <cp|s|cp>
|
|
! where s=s(r(t+dt)) and s'=s(r(t))
|
|
! for vanderbilt pseudo pot - kl & ap
|
|
!
|
|
use ions_base, only: na, nsp, nas => nax, nat
|
|
use cvan, only: ish, nvb
|
|
use uspp, only :nhsa=>nkb, qq
|
|
use uspp_param, only: nh
|
|
use electrons_base, only: n => nbsp, nx => nbspx, nspin, nupdwn, iupdwn, f
|
|
use gvecw, only: ngw
|
|
use control_flags, only: iprint, iprsta
|
|
use io_global, only: stdout
|
|
!
|
|
implicit none
|
|
!
|
|
complex(8) cp(ngw,n), phi(ngw,n), eigr(ngw,nat)
|
|
real(8) x0(nx,nx), diff, ccc, eps, delt
|
|
integer iter, max
|
|
real(8) bephi(nhsa,n), becp(nhsa,n)
|
|
!
|
|
real(8), allocatable :: diag(:), work1(:), work2(:), xloc(:,:), &
|
|
tmp1(:,:), tmp2(:,:), dd(:,:), x1(:,:), &
|
|
rhos(:,:), rhor(:,:), con(:,:), u(:,:), &
|
|
sig(:,:), rho(:,:), tau(:,:)
|
|
|
|
! the above are all automatic arrays
|
|
integer istart, nss, ifail, i, j, iss, iv, jv, ia, is, inl, jnl
|
|
real(8), allocatable:: qbephi(:,:), qbecp(:,:)
|
|
|
|
allocate( diag(nx), work1(nx), work2(nx), xloc(nx,nx), tmp1(nx,nx), &
|
|
tmp2(nx,nx), dd(nx,nx), x1(nx,nx), rhos(nx,nx), rhor(nx,nx), &
|
|
con(nx,nx), u(nx,nx), sig(nx,nx), rho(nx,nx), tau(nx,nx) )
|
|
|
|
!
|
|
! calculation of becp and bephi
|
|
!
|
|
call start_clock( 'ortho' )
|
|
call nlsm1(n,1,nvb,eigr, cp, becp)
|
|
call nlsm1(n,1,nvb,eigr,phi,bephi)
|
|
!
|
|
! calculation of qbephi and qbecp
|
|
!
|
|
allocate(qbephi(nhsa,n))
|
|
allocate(qbecp (nhsa,n))
|
|
qbephi = 0.d0
|
|
qbecp = 0.d0
|
|
!
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
do i=1,n
|
|
qbephi(inl,i)= qbephi(inl,i) &
|
|
& +qq(iv,jv,is)*bephi(jnl,i)
|
|
qbecp (inl,i)=qbecp (inl,i) &
|
|
& +qq(iv,jv,is)*becp (jnl,i)
|
|
end do
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
do iss=1,nspin
|
|
nss=nupdwn(iss)
|
|
istart=iupdwn(iss)
|
|
!
|
|
! rho = <s'c0|s|cp>
|
|
! sig = 1-<cp|s|cp>
|
|
! tau = <s'c0|s|s'c0>
|
|
!
|
|
call rhoset(cp,phi,bephi,qbecp,nss,istart,rho)
|
|
call sigset(cp,becp,qbecp,nss,istart,sig)
|
|
call tauset(phi,bephi,qbephi,nss,istart,tau)
|
|
!
|
|
if(iprsta.gt.4) then
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,'(26x,a)') ' rho '
|
|
do i=1,nss
|
|
WRITE( stdout,'(7f11.6)') (rho(i,j),j=1,nss)
|
|
end do
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,'(26x,a)') ' sig '
|
|
do i=1,nss
|
|
WRITE( stdout,'(7f11.6)') (sig(i,j),j=1,nss)
|
|
end do
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,'(26x,a)') ' tau '
|
|
do i=1,nss
|
|
WRITE( stdout,'(7f11.6)') (tau(i,j),j=1,nss)
|
|
end do
|
|
endif
|
|
!
|
|
!
|
|
!----------------------------------------------------------------by ap--
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
xloc(i,j) = x0(istart-1+i,istart-1+j)*ccc
|
|
dd(i,j) = 0.d0
|
|
x1(i,j) = 0.d0
|
|
tmp1(i,j)=0.d0
|
|
rhos(i,j)=0.5d0*( rho(i,j)+rho(j,i) )
|
|
!
|
|
! on some machines (IBM RS/6000 for instance) the following test allows
|
|
! to distinguish between Numbers and Sodium Nitride (NaN, Not a Number).
|
|
! If a matrix of Not-Numbers is passed to rs, the most likely outcome is
|
|
! that the program goes on forever doing nothing and writing nothing.
|
|
!
|
|
if (rhos(i,j).ne.rhos(i,j)) &
|
|
& call errore('ortho','ortho went bananas',1)
|
|
rhor(i,j)=rho(i,j)-rhos(i,j)
|
|
end do
|
|
end do
|
|
!
|
|
do i=1,nss
|
|
tmp1(i,i)=1.d0
|
|
end do
|
|
ifail=0
|
|
call start_clock( 'rsg' )
|
|
call rs(nx,nss,rhos,diag,1,u,work1,work2,ifail)
|
|
call stop_clock( 'rsg' )
|
|
!
|
|
! calculation of lagranges multipliers
|
|
!
|
|
do iter=1,max
|
|
!
|
|
! the following 4 MXMA-calls do the following matrix
|
|
! multiplications:
|
|
! tmp1 = x0*rhor (1st call)
|
|
! dd = x0*tau*x0 (2nd and 3rd call)
|
|
! tmp2 = x0*rhos (4th call)
|
|
!
|
|
call MXMA( xloc,1,nx,rhor,1,nx,tmp1,1,nx,nss,nss,nss)
|
|
call MXMA( tau ,1,nx,xloc,1,nx,tmp2,1,nx,nss,nss,nss)
|
|
call MXMA( xloc,1,nx,tmp2,1,nx, dd,1,nx,nss,nss,nss)
|
|
call MXMA( xloc,1,nx,rhos,1,nx,tmp2,1,nx,nss,nss,nss)
|
|
do i=1,nss
|
|
do j=1,nss
|
|
x1(i,j) = sig(i,j)-tmp1(i,j)-tmp1(j,i)-dd(i,j)
|
|
con(i,j)= x1(i,j)-tmp2(i,j)-tmp2(j,i)
|
|
end do
|
|
end do
|
|
!
|
|
! x1 = sig -x0*rho -x0*rho^t -x0*tau*x0
|
|
!
|
|
diff=0.d0
|
|
do i=1,nss
|
|
do j=1,nss
|
|
if(abs(con(i,j)).gt.diff) diff=abs(con(i,j))
|
|
end do
|
|
end do
|
|
!
|
|
if( diff.le.eps ) go to 20
|
|
!
|
|
! the following two MXMA-calls do:
|
|
! tmp1 = x1*u
|
|
! tmp2 = ut*x1*u
|
|
!
|
|
call MXMA(x1,1,nx, u,1,nx,tmp1,1,nx,nss,nss,nss)
|
|
call MXMA(u ,nx,1,tmp1,1,nx,tmp2,1,nx,nss,nss,nss)
|
|
!
|
|
! g=ut*x1*u/d (g is stored in tmp1)
|
|
!
|
|
do i=1,nss
|
|
do j=1,nss
|
|
tmp1(i,j)=tmp2(i,j)/(diag(i)+diag(j))
|
|
end do
|
|
end do
|
|
!
|
|
! the following two MXMA-calls do:
|
|
! tmp2 = g*ut
|
|
! x0 = u*g*ut
|
|
!
|
|
call MXMA(tmp1,1,nx, u,nx,1,tmp2,1,nx,nss,nss,nss)
|
|
call MXMA( u,1,nx,tmp2,1,nx,xloc,1,nx,nss,nss,nss)
|
|
end do
|
|
WRITE( stdout,*) ' diff= ',diff,' iter= ',iter
|
|
call errore('ortho','max number of iterations exceeded',iter)
|
|
!
|
|
20 continue
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
if(iprsta.gt.4) then
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,'(26x,a)') ' lambda '
|
|
do i=1,nss
|
|
WRITE( stdout,'(7f11.6)') (xloc(i,j)/f(i+istart-1),j=1,nss)
|
|
end do
|
|
endif
|
|
!
|
|
if(iprsta.gt.2) then
|
|
WRITE( stdout,*) ' diff= ',diff,' iter= ',iter
|
|
endif
|
|
!
|
|
! lagrange multipliers
|
|
!
|
|
do i=1,nss
|
|
do j=1,nss
|
|
x0(istart-1+i,istart-1+j)=xloc(i,j)/ccc
|
|
if (xloc(i,j).ne.xloc(i,j)) &
|
|
& call errore('ortho','ortho went bananas',2)
|
|
end do
|
|
end do
|
|
!
|
|
end do
|
|
!
|
|
deallocate(qbecp )
|
|
deallocate(qbephi)
|
|
deallocate( diag, work1, work2, xloc, tmp1, tmp2, dd, x1, rhos, rhor, &
|
|
con, u, sig, rho, tau )
|
|
!
|
|
call stop_clock( 'ortho' )
|
|
return
|
|
end subroutine ortho
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine pbc(rin,a1,a2,a3,ainv,rout)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! brings atoms inside the unit cell
|
|
!
|
|
implicit none
|
|
! input
|
|
real(8) rin(3), a1(3),a2(3),a3(3), ainv(3,3)
|
|
! output
|
|
real(8) rout(3)
|
|
! local
|
|
real(8) x,y,z
|
|
!
|
|
! bring atomic positions to crystal axis
|
|
!
|
|
x = ainv(1,1)*rin(1)+ainv(1,2)*rin(2)+ainv(1,3)*rin(3)
|
|
y = ainv(2,1)*rin(1)+ainv(2,2)*rin(2)+ainv(2,3)*rin(3)
|
|
z = ainv(3,1)*rin(1)+ainv(3,2)*rin(2)+ainv(3,3)*rin(3)
|
|
!
|
|
! bring x,y,z in the range between -0.5 and 0.5
|
|
!
|
|
x = x - nint(x)
|
|
y = y - nint(y)
|
|
z = z - nint(z)
|
|
!
|
|
! bring atomic positions back in cartesian axis
|
|
!
|
|
rout(1) = x*a1(1)+y*a2(1)+z*a3(1)
|
|
rout(2) = x*a1(2)+y*a2(2)+z*a3(2)
|
|
rout(3) = x*a1(3)+y*a2(3)+z*a3(3)
|
|
!
|
|
return
|
|
end subroutine pbc
|
|
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine prefor(eigr,betae)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! input : eigr = e^-ig.r_i
|
|
! output: betae_i,i(g) = (-i)**l beta_i,i(g) e^-ig.r_i
|
|
!
|
|
use ions_base, only: nas => nax, nsp, na, nat
|
|
use gvecw, only: ngw
|
|
use cvan, only: ish
|
|
use uspp, only :nhsa=>nkb, beta, nhtol
|
|
use uspp_param, only: nh
|
|
!
|
|
implicit none
|
|
complex(8) eigr(ngw,nat)
|
|
complex(8) betae(ngw,nhsa)
|
|
!
|
|
integer is, iv, ia, inl, ig, isa
|
|
complex(8) ci
|
|
!
|
|
call start_clock( 'prefor' )
|
|
isa = 0
|
|
do is=1,nsp
|
|
do iv=1,nh(is)
|
|
ci=(0.,-1.)**nhtol(iv,is)
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
do ig=1,ngw
|
|
betae(ig,inl)=ci*beta(ig,iv,is)*eigr(ig,ia+isa)
|
|
end do
|
|
end do
|
|
end do
|
|
isa = isa + na(is)
|
|
end do
|
|
call stop_clock( 'prefor' )
|
|
!
|
|
return
|
|
end subroutine prefor
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine projwfc(c,eigr,betae)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! Projection on atomic wavefunctions
|
|
!
|
|
use io_global, only: stdout
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use ions_base, only: nsp, na, nas => nax, nat
|
|
use uspp, only: nhsa => nkb
|
|
use atom
|
|
!
|
|
implicit none
|
|
complex(8), intent(in) :: c(ngw,nx), eigr(ngw,nat), &
|
|
& betae(ngw,nhsa)
|
|
!
|
|
complex(8), allocatable:: wfc(:,:), swfc(:,:), becwfc(:,:)
|
|
real(8), allocatable :: overlap(:,:), e(:), z(:,:), &
|
|
& proj(:,:), temp(:)
|
|
real(8) :: somma
|
|
integer n_atomic_wfc
|
|
integer is, ia, nb, l, m, k, i
|
|
!
|
|
! calculate number of atomic states
|
|
!
|
|
n_atomic_wfc=0
|
|
do is=1,nsp
|
|
do nb = 1,nchi(is)
|
|
l = lchi(nb,is)
|
|
n_atomic_wfc = n_atomic_wfc + (2*l+1)*na(is)
|
|
end do
|
|
end do
|
|
if (n_atomic_wfc.eq.0) return
|
|
!
|
|
allocate(wfc(ngw,n_atomic_wfc))
|
|
!
|
|
! calculate wfc = atomic states
|
|
!
|
|
call atomic_wfc(eigr,n_atomic_wfc,wfc)
|
|
!
|
|
! calculate bec = <beta|wfc>
|
|
!
|
|
allocate(becwfc(nhsa,n_atomic_wfc))
|
|
call nlsm1 (n_atomic_wfc,1,nsp,eigr,wfc,becwfc)
|
|
|
|
! calculate swfc = S|wfc>
|
|
!
|
|
allocate(swfc(ngw,n_atomic_wfc))
|
|
call s_wfc(n_atomic_wfc,becwfc,betae,wfc,swfc)
|
|
!
|
|
! calculate overlap(i,j) = <wfc_i|S|wfc_j>
|
|
!
|
|
allocate(overlap(n_atomic_wfc,n_atomic_wfc))
|
|
!
|
|
call MXMA(wfc,2*ngw,1,swfc,1,2*ngw,overlap,1, &
|
|
& n_atomic_wfc,n_atomic_wfc,2*ngw,n_atomic_wfc)
|
|
|
|
call reduce(n_atomic_wfc**2,overlap)
|
|
|
|
overlap=overlap*2.d0
|
|
if (gstart == 2) then
|
|
do l=1,n_atomic_wfc
|
|
do m=1,n_atomic_wfc
|
|
overlap(m,l)=overlap(m,l)-DBLE(wfc(1,m))*DBLE(swfc(1,l))
|
|
end do
|
|
end do
|
|
end if
|
|
!
|
|
! calculate (overlap)^(-1/2)(i,j). An orthonormal set of vectors |wfc_i>
|
|
! is obtained by introducing |wfc_j>=(overlap)^(-1/2)(i,j)*S|wfc_i>
|
|
!
|
|
allocate(z(n_atomic_wfc,n_atomic_wfc))
|
|
allocate(e(n_atomic_wfc))
|
|
call rdiag(n_atomic_wfc,overlap,n_atomic_wfc,e,z)
|
|
overlap=0.d0
|
|
do l=1,n_atomic_wfc
|
|
do m=1,n_atomic_wfc
|
|
do k=1,n_atomic_wfc
|
|
overlap(l,m)=overlap(l,m)+z(m,k)*z(l,k)/sqrt(e(k))
|
|
end do
|
|
end do
|
|
end do
|
|
deallocate(e)
|
|
deallocate(z)
|
|
!
|
|
! calculate |wfc_j>=(overlap)^(-1/2)(i,j)*S|wfc_i> (note the S matrix!)
|
|
!
|
|
wfc=0.d0
|
|
do m=1,n_atomic_wfc
|
|
do l=1,n_atomic_wfc
|
|
wfc(:,m)=wfc(:,m)+overlap(l,m)*swfc(:,l)
|
|
end do
|
|
end do
|
|
deallocate(overlap)
|
|
deallocate(swfc)
|
|
deallocate(becwfc)
|
|
!
|
|
! calculate proj = <c|S|wfc>
|
|
!
|
|
allocate(proj(n,n_atomic_wfc))
|
|
allocate(temp(ngw))
|
|
do m=1,n
|
|
do l=1,n_atomic_wfc
|
|
temp(:)=DBLE(CONJG(c(:,m))*wfc(:,l))
|
|
proj(m,l)=2.d0*SUM(temp)
|
|
if (gstart == 2) proj(m,l)=proj(m,l)-temp(1)
|
|
end do
|
|
end do
|
|
deallocate(temp)
|
|
|
|
call reduce(n*n_atomic_wfc,proj)
|
|
|
|
i=0
|
|
WRITE( stdout,'(/''Projection on atomic states:'')')
|
|
do is=1,nsp
|
|
do nb = 1,nchi(is)
|
|
l=lchi(nb,is)
|
|
do m = -l,l
|
|
do ia=1,na(is)
|
|
i=i+1
|
|
WRITE( stdout,'(''atomic state # '',i3,'': atom # '',i3, &
|
|
& '' species # '',i2,'' wfc # '',i2, &
|
|
& '' (l='',i1,'' m='',i2,'')'')') &
|
|
& i, ia, is, nb, l, m
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
|
|
WRITE( stdout,*)
|
|
do m=1,n
|
|
somma=0.d0
|
|
do l=1,n_atomic_wfc
|
|
somma=somma+proj(m,l)**2
|
|
end do
|
|
WRITE( stdout,'(''state # '',i4,'' sum c^2 ='',f7.4)') m,somma
|
|
WRITE( stdout,'(10f7.4)') (abs(proj(m,l)),l=1,n_atomic_wfc)
|
|
end do
|
|
!
|
|
deallocate(proj)
|
|
deallocate(wfc)
|
|
return
|
|
end subroutine projwfc
|
|
!-----------------------------------------------------------------------
|
|
subroutine raddrizza(nspin,nx,nupdwn,iupdwn,f,lambda,ngw,c)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! transform wavefunctions into eigenvectors of the hamiltonian
|
|
! via diagonalization of the constraint matrix lambda
|
|
!
|
|
implicit none
|
|
integer, intent(in) :: nspin, nx, ngw, nupdwn(nspin), &
|
|
& iupdwn(nspin)
|
|
real (8), intent(in) :: lambda(nx,nx), f(nx)
|
|
complex(8), intent(inout):: c(ngw,nx)
|
|
|
|
real(8) :: lambdar(nx,nx), wr(nx), zr(nx,nx)
|
|
complex(8), allocatable:: csave(:,:)
|
|
integer :: iss, n, j, i, i0
|
|
!
|
|
do iss=1,nspin
|
|
n=nupdwn(iss)
|
|
i0=iupdwn(iss)-1
|
|
allocate(csave(ngw,n))
|
|
do i=1,n
|
|
do j=1,n
|
|
lambdar(j,i)=lambda(i0+j,i0+i)
|
|
end do
|
|
end do
|
|
|
|
call rdiag(n,lambdar,nx,wr,zr)
|
|
|
|
csave=0.d0
|
|
do i=1,n
|
|
do j=1,n
|
|
csave(:,i) = csave(:,i) + zr(j,i)*c(:,i0+j)
|
|
end do
|
|
end do
|
|
do i=1,n
|
|
c(:,i0+i)=csave(:,i)
|
|
end do
|
|
deallocate(csave)
|
|
|
|
! uncomment to print out eigenvalues
|
|
! do i=1,n
|
|
! if (f(i0+i).gt.1.e-6) then
|
|
! wr(i)=27.212*wr(i)/f(i0+i)
|
|
! else
|
|
! wr(i)=0.0
|
|
! end if
|
|
! end do
|
|
! WRITE( stdout,'(/10f8.2/)') (wr(i),i=1,nupdwn(iss))
|
|
end do
|
|
return
|
|
end subroutine raddrizza
|
|
!
|
|
!---------------------------------------------------------------------
|
|
subroutine randin(nmin,nmax,gstart,ngw,ampre,c)
|
|
!---------------------------------------------------------------------
|
|
!
|
|
use wave_functions, only: wave_rand_init
|
|
implicit none
|
|
|
|
! input
|
|
integer nmin, nmax, gstart, ngw
|
|
real(8) ampre
|
|
! output
|
|
complex(8) c(ngw,nmax)
|
|
! local
|
|
integer i,j
|
|
real(8) ranf1, randy, ranf2, ampexp
|
|
!
|
|
CALL wave_rand_init( c )
|
|
! do i=nmin,nmax
|
|
! do j=gstart,ngw
|
|
! ranf1=.5-randy()
|
|
! ranf2=.5-randy()
|
|
! ampexp=ampre*exp(-(4.*j)/ngw)
|
|
! c(j,i)=c(j,i)+ampexp*CMPLX(ranf1,ranf2)
|
|
! end do
|
|
! end do
|
|
!
|
|
return
|
|
end subroutine randin
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine rdiag (n,h,ldh,e,v)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! calculates all the eigenvalues and eigenvectors of a complex
|
|
! hermitean matrix H . On output, the matrix H is destroyed
|
|
!
|
|
implicit none
|
|
integer, intent(in) :: n, ldh
|
|
complex(8), intent(inout):: h(ldh,n)
|
|
real (8), intent(out) :: e(n)
|
|
complex(8), intent(out) :: v(ldh,n)
|
|
!
|
|
real(8) fv1(n), fv2(n)
|
|
integer ierr
|
|
!
|
|
call rs(ldh,n,h,e,1,v,fv1,fv2,ierr)
|
|
!
|
|
return
|
|
end subroutine rdiag
|
|
!-----------------------------------------------------------------------
|
|
subroutine rhoofr (nfi,c,irb,eigrb,bec,rhovan,rhor,rhog,rhos,enl,ekin)
|
|
!-----------------------------------------------------------------------
|
|
! the normalized electron density rhor in real space
|
|
! the kinetic energy ekin
|
|
! subroutine uses complex fft so it computes two ft's
|
|
! simultaneously
|
|
!
|
|
! rho_i,ij = sum_n < beta_i,i | psi_n >< psi_n | beta_i,j >
|
|
! < psi_n | beta_i,i > = c_n(0) beta_i,i(0) +
|
|
! 2 sum_g> re(c_n*(g) (-i)**l beta_i,i(g) e^-ig.r_i)
|
|
!
|
|
! e_v = sum_i,ij rho_i,ij d^ion_is,ji
|
|
!
|
|
use kinds, only: dp
|
|
use control_flags, only: iprint, tbuff, iprsta, thdyn, tpre, trhor
|
|
use ions_base, only: nat, nas => nax, nsp
|
|
use parameters, only: natx, nsx
|
|
use gvecp, only: ng => ngm
|
|
use gvecs
|
|
use gvecb, only: ngb
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use recvecs_indexes, only: np, nm
|
|
use uspp, only: nhsa => nkb
|
|
use uspp_param, only: nh, nhm
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nr3x, nnr => nnrx
|
|
use cell_base, only: omega
|
|
use smooth_grid_dimensions, only: nr1s, nr2s, nr3s, &
|
|
nr1sx, nr2sx, nr3sx, nnrsx
|
|
use electrons_base, only: nx => nbspx, n => nbsp, f, ispin => fspin, nspin
|
|
use constants, only: pi, fpi
|
|
use mp, ONLY: mp_sum
|
|
! use local_pseudo
|
|
!
|
|
use cdvan
|
|
use dener
|
|
use io_global, only: stdout
|
|
use funct, only: ismeta
|
|
use cg_module, only : tcg
|
|
!
|
|
implicit none
|
|
real(8) bec(nhsa,n), rhovan(nhm*(nhm+1)/2,nat,nspin)
|
|
real(8) rhor(nnr,nspin), rhos(nnrsx,nspin)
|
|
real(8) enl, ekin
|
|
complex(8) eigrb(ngb,nat), c(ngw,nx), rhog(ng,nspin)
|
|
integer irb(3,nat), nfi
|
|
! local variables
|
|
integer iss, isup, isdw, iss1, iss2, ios, i, ir, ig
|
|
real(8) rsumr(2), rsumg(2), sa1, sa2
|
|
real(8) rnegsum, rmin, rmax, rsum
|
|
real(8), external :: enkin, ennl
|
|
complex(8) ci,fp,fm
|
|
complex(8), allocatable :: psi(:), psis(:)
|
|
!
|
|
!
|
|
call start_clock( 'rhoofr' )
|
|
allocate( psi( nnr ) )
|
|
allocate( psis( nnrsx ) )
|
|
ci=(0.0,1.0)
|
|
do iss=1,nspin
|
|
rhor(:,iss) = 0.d0
|
|
rhos(:,iss) = 0.d0
|
|
rhog(:,iss) = (0.d0, 0.d0)
|
|
end do
|
|
!
|
|
! ==================================================================
|
|
! calculation of kinetic energy ekin
|
|
! ==================================================================
|
|
ekin=enkin(c)
|
|
if(tpre) call denkin(c,dekin)
|
|
!
|
|
! ==================================================================
|
|
! calculation of non-local energy
|
|
! ==================================================================
|
|
enl=ennl(rhovan, bec)
|
|
if(tpre) call dennl(bec,denl)
|
|
!
|
|
! warning! trhor and thdyn are not compatible yet!
|
|
!
|
|
if(trhor.and.(.not.thdyn))then
|
|
! ==================================================================
|
|
! charge density is read from unit 47
|
|
! ==================================================================
|
|
#ifdef __PARA
|
|
call read_rho(47,nspin,rhor)
|
|
#else
|
|
read(47) ((rhor(ir,iss),ir=1,nnr),iss=1,nspin)
|
|
#endif
|
|
rewind 47
|
|
!
|
|
if(nspin.eq.1)then
|
|
iss=1
|
|
do ir=1,nnr
|
|
psi(ir)=CMPLX(rhor(ir,iss),0.d0)
|
|
end do
|
|
call fwfft(psi,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ig=1,ng
|
|
rhog(ig,iss)=psi(np(ig))
|
|
end do
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ir=1,nnr
|
|
psi(ir)=CMPLX(rhor(ir,isup),rhor(ir,isdw))
|
|
end do
|
|
call fwfft(psi,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ig=1,ng
|
|
fp=psi(np(ig))+psi(nm(ig))
|
|
fm=psi(np(ig))-psi(nm(ig))
|
|
rhog(ig,isup)=0.5*CMPLX( DBLE(fp),AIMAG(fm))
|
|
rhog(ig,isdw)=0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
endif
|
|
!
|
|
else
|
|
|
|
! ==================================================================
|
|
! self-consistent charge
|
|
! ==================================================================
|
|
!
|
|
! important: if n is odd then nx must be .ge.n+1 and c(*,n+1)=0.
|
|
!
|
|
if (mod(n,2).ne.0) then
|
|
do ig=1,ngw
|
|
c(ig,n+1)=(0.,0.)
|
|
end do
|
|
endif
|
|
!
|
|
do i=1,n,2
|
|
psis (:) = (0.d0, 0.d0)
|
|
do ig=1,ngw
|
|
psis(nms(ig))=CONJG(c(ig,i))+ci*conjg(c(ig,i+1))
|
|
psis(nps(ig))=c(ig,i)+ci*c(ig,i+1)
|
|
! write(6,'(I6,4F15.10)') ig, psis(nms(ig)), psis(nps(ig))
|
|
end do
|
|
|
|
call ivfftw(psis,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
|
|
! wavefunctions in unit 21
|
|
!
|
|
#if defined(__CRAYY)
|
|
if(tbuff) buffer out(21,0) (psis(1),psis(nnrsx))
|
|
#else
|
|
if(tbuff) write(21,iostat=ios) psis
|
|
#endif
|
|
iss1=ispin(i)
|
|
sa1=f(i)/omega
|
|
if (i.ne.n) then
|
|
iss2=ispin(i+1)
|
|
sa2=f(i+1)/omega
|
|
else
|
|
iss2=iss1
|
|
sa2=0.0
|
|
end if
|
|
do ir=1,nnrsx
|
|
rhos(ir,iss1)=rhos(ir,iss1) + sa1*( DBLE(psis(ir)))**2
|
|
rhos(ir,iss2)=rhos(ir,iss2) + sa2*(AIMAG(psis(ir)))**2
|
|
end do
|
|
|
|
!
|
|
! buffer 21
|
|
!
|
|
if(tbuff) then
|
|
#if defined(__CRAYY)
|
|
ios=unit(21)
|
|
#endif
|
|
if(ios.ne.0) call errore(' rhoofr',' error in writing unit 21',ios)
|
|
endif
|
|
!
|
|
end do
|
|
!
|
|
if(tbuff) rewind 21
|
|
!
|
|
! smooth charge in g-space is put into rhog(ig)
|
|
!
|
|
if(nspin.eq.1)then
|
|
iss=1
|
|
do ir=1,nnrsx
|
|
psis(ir)=CMPLX(rhos(ir,iss),0.d0)
|
|
end do
|
|
call fwffts(psis,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
do ig=1,ngs
|
|
rhog(ig,iss)=psis(nps(ig))
|
|
end do
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ir=1,nnrsx
|
|
psis(ir)=CMPLX(rhos(ir,isup),rhos(ir,isdw))
|
|
end do
|
|
call fwffts(psis,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
do ig=1,ngs
|
|
fp= psis(nps(ig)) + psis(nms(ig))
|
|
fm= psis(nps(ig)) - psis(nms(ig))
|
|
rhog(ig,isup)=0.5*CMPLX( DBLE(fp),AIMAG(fm))
|
|
rhog(ig,isdw)=0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
endif
|
|
!
|
|
if(nspin.eq.1) then
|
|
!
|
|
! case nspin=1
|
|
!
|
|
iss=1
|
|
psi (:) = (0.d0, 0.d0)
|
|
do ig=1,ngs
|
|
psi(nm(ig))=CONJG(rhog(ig,iss))
|
|
psi(np(ig))= rhog(ig,iss)
|
|
end do
|
|
call invfft(psi,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ir=1,nnr
|
|
rhor(ir,iss)=DBLE(psi(ir))
|
|
end do
|
|
else
|
|
!
|
|
! case nspin=2
|
|
!
|
|
isup=1
|
|
isdw=2
|
|
psi (:) = (0.d0, 0.d0)
|
|
do ig=1,ngs
|
|
psi(nm(ig))=CONJG(rhog(ig,isup))+ci*conjg(rhog(ig,isdw))
|
|
psi(np(ig))=rhog(ig,isup)+ci*rhog(ig,isdw)
|
|
end do
|
|
call invfft(psi,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ir=1,nnr
|
|
rhor(ir,isup)= DBLE(psi(ir))
|
|
rhor(ir,isdw)=AIMAG(psi(ir))
|
|
end do
|
|
endif
|
|
if (ismeta) call kedtauofr_meta(c, psi, psis) ! METAGGA
|
|
!
|
|
if(iprsta.ge.3)then
|
|
do iss=1,nspin
|
|
rsumg(iss)=omega*DBLE(rhog(1,iss))
|
|
rsumr(iss)=SUM(rhor(:,iss))*omega/DBLE(nr1*nr2*nr3)
|
|
end do
|
|
|
|
if ( gstart /= 2 ) then
|
|
!
|
|
! in the parallel case, only one processor has G=0 !
|
|
!
|
|
do iss=1,nspin
|
|
rsumg(iss)=0.0
|
|
end do
|
|
end if
|
|
call mp_sum( rsumg( 1:nspin ) )
|
|
call mp_sum( rsumr( 1:nspin ) )
|
|
|
|
if ( nspin == 1 ) then
|
|
WRITE( stdout, 10) rsumg(1), rsumr(1)
|
|
else
|
|
WRITE( stdout, 20) rsumg(1), rsumr(1), rsumg(2), rsumr(2)
|
|
endif
|
|
|
|
endif
|
|
!
|
|
! add vanderbilt contribution to the charge density
|
|
! drhov called before rhov because input rho must be the smooth part
|
|
!
|
|
if (tpre) call drhov(irb,eigrb,rhovan,rhog,rhor)
|
|
!
|
|
call rhov(irb,eigrb,rhovan,rhog,rhor)
|
|
|
|
endif
|
|
|
|
! ======================================endif for trhor=============
|
|
!
|
|
! here to check the integral of the charge density
|
|
!
|
|
!
|
|
if(iprsta.ge.2) then
|
|
call checkrho(nnr,nspin,rhor,rmin,rmax,rsum,rnegsum)
|
|
rnegsum=rnegsum*omega/DBLE(nr1*nr2*nr3)
|
|
rsum=rsum*omega/DBLE(nr1*nr2*nr3)
|
|
WRITE( stdout,'(a,4(1x,f12.6))') &
|
|
& ' rhoofr: rmin rmax rnegsum rsum ',rmin,rmax,rnegsum,rsum
|
|
end if
|
|
!
|
|
if( nfi == 0 .or. mod(nfi, iprint) == 0 .and. .not. tcg) then
|
|
|
|
do iss=1,nspin
|
|
rsumg(iss)=omega*DBLE(rhog(1,iss))
|
|
rsumr(iss)=SUM(rhor(:,iss),1)*omega/DBLE(nr1*nr2*nr3)
|
|
end do
|
|
|
|
if (gstart.ne.2) then
|
|
! in the parallel case, only one processor has G=0 !
|
|
do iss=1,nspin
|
|
rsumg(iss)=0.0
|
|
end do
|
|
end if
|
|
|
|
call mp_sum( rsumg( 1:nspin ) )
|
|
call mp_sum( rsumr( 1:nspin ) )
|
|
|
|
if ( nspin == 1 ) then
|
|
WRITE( stdout, 10) rsumg(1), rsumr(1)
|
|
else
|
|
WRITE( stdout, 20) rsumg(1), rsumr(1), rsumg(2), rsumr(2)
|
|
endif
|
|
|
|
endif
|
|
|
|
deallocate( psi )
|
|
deallocate( psis )
|
|
|
|
10 FORMAT( /, 3X, 'from rhoofr: total integrated electronic density', &
|
|
& /, 3X, 'in g-space = ', f11.6, 3x, 'in r-space =', f11.6 )
|
|
20 FORMAT( /, 3X, 'from rhoofr: total integrated electronic density', &
|
|
& /, 3X, 'spin up', &
|
|
& /, 3X, 'in g-space = ', f11.6, 3x, 'in r-space =', f11.6 , &
|
|
& /, 3X, 'spin down', &
|
|
& /, 3X, 'in g-space = ', f11.6, 3x, 'in r-space =', f11.6 )
|
|
!
|
|
call stop_clock( 'rhoofr' )
|
|
|
|
!
|
|
return
|
|
end subroutine rhoofr
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine rhoset(cp,phi,bephi,qbecp,nss,ist,rho)
|
|
!-----------------------------------------------------------------------
|
|
! input: cp (non-orthonormal), phi, bephi, qbecp
|
|
! computes the matrix
|
|
! rho = <s'c0|s cp> = <phi|s cp>
|
|
! where |phi> = s'|c0> = |c0> + sum q_ij |i><j|c0>
|
|
! where s=s(r(t+dt)) and s'=s(r(t))
|
|
! routine makes use of c(-q)=c*(q)
|
|
!
|
|
use parameters, only: nsx, natx
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus
|
|
use cvan, only: nvb
|
|
use electrons_base, only: nx => nbspx, n => nbsp ! , f, ispin => fspin, nspin
|
|
!
|
|
implicit none
|
|
!
|
|
integer nss, ist
|
|
complex(8) cp(ngw,n), phi(ngw,n)
|
|
real(8) bephi(nhsa,n), qbecp(nhsa,n), rho(nx,nx)
|
|
integer i, j
|
|
real(8) tmp1(nx,nx) ! automatic array
|
|
!
|
|
rho (:,:) = 0.d0
|
|
!
|
|
! <phi|cp>
|
|
!
|
|
call MXMA(phi(1,ist),2*ngw,1,cp(1,ist),1,2*ngw, &
|
|
& rho,1,nx,nss,2*ngw,nss)
|
|
!
|
|
! q >= 0 components with weight 2.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
rho(i,j)=2.*rho(i,j)
|
|
end do
|
|
end do
|
|
!
|
|
if (gstart == 2) then
|
|
!
|
|
! q = 0 components has weight 1.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
rho(i,j) = rho(i,j) - &
|
|
& DBLE(phi(1,i+ist-1))*DBLE(cp(1,j+ist-1))
|
|
end do
|
|
end do
|
|
end if
|
|
|
|
call reduce(nx*nss,rho)
|
|
!
|
|
if(nvb.gt.0)then
|
|
tmp1 (:,:) = 0.d0
|
|
!
|
|
call MXMA(bephi(1,ist),nhsa,1,qbecp(1,ist),1,nhsa, &
|
|
& tmp1,1,nx,nss,nhsavb,nss)
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
rho(i,j)=rho(i,j)+tmp1(i,j)
|
|
end do
|
|
end do
|
|
endif
|
|
!
|
|
return
|
|
end subroutine rhoset
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine rhov(irb,eigrb,rhovan,rhog,rhor)
|
|
!-----------------------------------------------------------------------
|
|
! Add Vanderbilt contribution to rho(r) and rho(g)
|
|
!
|
|
! n_v(g) = sum_i,ij rho_i,ij q_i,ji(g) e^-ig.r_i
|
|
!
|
|
! routine makes use of c(-g)=c*(g) and beta(-g)=beta*(g)
|
|
!
|
|
use kinds, only: dp
|
|
use ions_base, only: nas => nax, nat, na, nsp
|
|
use io_global, only: stdout
|
|
use parameters, only: natx, nsx
|
|
use cvan, only: nvb
|
|
use uspp_param, only: nh, nhm
|
|
use uspp, only: deeq
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nr3x, nnr => nnrx
|
|
use electrons_base, only: nspin
|
|
use gvecb
|
|
use gvecp, only: ng => ngm
|
|
use cell_base, only: omega
|
|
use small_box, only: omegab
|
|
use smallbox_grid_dimensions, only: nr1b, nr2b, nr3b, &
|
|
nr1bx, nr2bx, nr3bx, nnrb => nnrbx
|
|
use control_flags, only: iprint, iprsta
|
|
use qgb_mod
|
|
use para_mod
|
|
use recvecs_indexes, only: np, nm
|
|
!
|
|
implicit none
|
|
!
|
|
real(8) :: rhovan(nhm*(nhm+1)/2,nat,nspin)
|
|
integer, intent(in) :: irb(3,nat)
|
|
complex(8), intent(in):: eigrb(ngb,nat)
|
|
real(8), intent(inout):: rhor(nnr,nspin)
|
|
complex(8), intent(inout):: rhog(ng,nspin)
|
|
!
|
|
integer isup, isdw, nfft, ifft, iv, jv, ig, ijv, is, iss, &
|
|
& isa, ia, ir, irb3, imin3, imax3
|
|
real(8) sumrho
|
|
complex(8) ci, fp, fm, ca
|
|
complex(8), allocatable:: qgbt(:,:)
|
|
complex(8), allocatable:: v(:)
|
|
complex(8), allocatable:: qv(:)
|
|
!
|
|
if (nvb.eq.0) return
|
|
call start_clock( 'rhov' )
|
|
ci=(0.,1.)
|
|
!
|
|
!
|
|
allocate( v( nnr ) )
|
|
allocate( qv( nnrb ) )
|
|
v (:) = (0.d0, 0.d0)
|
|
allocate( qgbt( ngb, 2 ) )
|
|
|
|
!
|
|
if(nspin.eq.1) then
|
|
!
|
|
! nspin=1 : two fft at a time, one per atom, if possible
|
|
!
|
|
iss=1
|
|
isa=1
|
|
|
|
do is = 1, nvb
|
|
|
|
#ifdef __PARA
|
|
|
|
do ia=1,na(is)
|
|
nfft=1
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 15
|
|
#else
|
|
|
|
do ia = 1, na(is), 2
|
|
nfft = 2
|
|
if( ia .eq. na(is) ) nfft = 1
|
|
|
|
#endif
|
|
|
|
!
|
|
! nfft=2 if two ffts at the same time are performed
|
|
!
|
|
do ifft=1,nfft
|
|
qgbt(:,ifft) = (0.d0, 0.d0)
|
|
ijv=0
|
|
do iv= 1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
sumrho=rhovan(ijv,isa+ifft-1,iss)
|
|
if(iv.ne.jv) sumrho=2.*sumrho
|
|
do ig=1,ngb
|
|
qgbt(ig,ifft)=qgbt(ig,ifft) + sumrho*qgb(ig,ijv,is)
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
! add structure factor
|
|
!
|
|
qv(:) = (0.d0, 0.d0)
|
|
if(nfft.eq.2)then
|
|
do ig=1,ngb
|
|
qv(npb(ig))= &
|
|
eigrb(ig,isa )*qgbt(ig,1) &
|
|
+ ci* eigrb(ig,isa+1)*qgbt(ig,2)
|
|
qv(nmb(ig))= &
|
|
CONJG(eigrb(ig,isa )*qgbt(ig,1)) &
|
|
+ ci*CONJG(eigrb(ig,isa+1)*qgbt(ig,2))
|
|
end do
|
|
else
|
|
do ig=1,ngb
|
|
qv(npb(ig)) = eigrb(ig,isa)*qgbt(ig,1)
|
|
qv(nmb(ig)) = CONJG(eigrb(ig,isa)*qgbt(ig,1))
|
|
end do
|
|
endif
|
|
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
|
|
!
|
|
! qv = US augmentation charge in real space on box grid
|
|
! for atomic species is, real(qv)=atom ia, imag(qv)=atom ia+1
|
|
|
|
if(iprsta.gt.2) then
|
|
ca = SUM(qv)
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: 1-atom g-sp = ', &
|
|
& omegab*DBLE(qgbt(1,1))
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: 1-atom r-sp = ', &
|
|
& omegab*DBLE(ca)/(nr1b*nr2b*nr3b)
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: 1-atom g-sp = ', &
|
|
& omegab*DBLE(qgbt(1,2))
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: 1-atom r-sp = ', &
|
|
& omegab*AIMAG(ca)/(nr1b*nr2b*nr3b)
|
|
endif
|
|
!
|
|
! add qv(r) to v(r), in real space on the dense grid
|
|
!
|
|
call box2grid(irb(1,isa),1,qv,v)
|
|
if (nfft.eq.2) call box2grid(irb(1,isa+1),2,qv,v)
|
|
15 isa=isa+nfft
|
|
!
|
|
end do
|
|
end do
|
|
!
|
|
! rhor(r) = total (smooth + US) charge density in real space
|
|
!
|
|
do ir=1,nnr
|
|
rhor(ir,iss)=rhor(ir,iss)+DBLE(v(ir))
|
|
end do
|
|
!
|
|
if(iprsta.gt.2) then
|
|
ca = SUM(v)
|
|
|
|
call reduce(2,ca)
|
|
|
|
WRITE( stdout,'(a,2f12.8)') &
|
|
& ' rhov: int n_v(r) dr = ',omega*ca/(nr1*nr2*nr3)
|
|
endif
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
if(iprsta.gt.2) then
|
|
WRITE( stdout,*) ' rhov: smooth ',omega*rhog(1,iss)
|
|
WRITE( stdout,*) ' rhov: vander ',omega*v(1)
|
|
WRITE( stdout,*) ' rhov: all ',omega*(rhog(1,iss)+v(1))
|
|
endif
|
|
!
|
|
! rhog(g) = total (smooth + US) charge density in G-space
|
|
!
|
|
do ig=1,ng
|
|
rhog(ig,iss)=rhog(ig,iss)+v(np(ig))
|
|
end do
|
|
!
|
|
if(iprsta.gt.1) WRITE( stdout,'(a,2f12.8)') &
|
|
& ' rhov: n_v(g=0) = ',omega*DBLE(rhog(1,iss))
|
|
!
|
|
else
|
|
!
|
|
! nspin=2: two fft at a time, one for spin up and one for spin down
|
|
!
|
|
isup=1
|
|
isdw=2
|
|
isa=1
|
|
do is=1,nvb
|
|
do ia=1,na(is)
|
|
#ifdef __PARA
|
|
irb3=irb(3,isa)
|
|
call parabox(nr3b,irb3,nr3,imin3,imax3)
|
|
if (imax3-imin3+1.le.0) go to 25
|
|
#endif
|
|
do iss=1,2
|
|
qgbt(:,iss) = (0.d0, 0.d0)
|
|
ijv=0
|
|
do iv=1,nh(is)
|
|
do jv=iv,nh(is)
|
|
ijv=ijv+1
|
|
sumrho=rhovan(ijv,isa,iss)
|
|
if(iv.ne.jv) sumrho=2.*sumrho
|
|
do ig=1,ngb
|
|
qgbt(ig,iss)=qgbt(ig,iss)+sumrho*qgb(ig,ijv,is)
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
! add structure factor
|
|
!
|
|
qv(:) = (0.d0, 0.d0)
|
|
do ig=1,ngb
|
|
qv(npb(ig)) = eigrb(ig,isa)*qgbt(ig,1) &
|
|
& + ci* eigrb(ig,isa)*qgbt(ig,2)
|
|
qv(nmb(ig)) = CONJG(eigrb(ig,isa)*qgbt(ig,1)) &
|
|
& + ci* CONJG(eigrb(ig,isa)*qgbt(ig,2))
|
|
end do
|
|
!
|
|
call ivfftb(qv,nr1b,nr2b,nr3b,nr1bx,nr2bx,nr3bx,irb3)
|
|
!
|
|
! qv is the now the US augmentation charge for atomic species is
|
|
! and atom ia: real(qv)=spin up, imag(qv)=spin down
|
|
!
|
|
if(iprsta.gt.2) then
|
|
ca = SUM(qv)
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: up g-space = ', &
|
|
& omegab*DBLE(qgbt(1,1))
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: up r-sp = ', &
|
|
& omegab*DBLE(ca)/(nr1b*nr2b*nr3b)
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: dw g-space = ', &
|
|
& omegab*DBLE(qgbt(1,2))
|
|
WRITE( stdout,'(a,f12.8)') ' rhov: dw r-sp = ', &
|
|
& omegab*AIMAG(ca)/(nr1b*nr2b*nr3b)
|
|
endif
|
|
!
|
|
! add qv(r) to v(r), in real space on the dense grid
|
|
!
|
|
call box2grid2(irb(1,isa),qv,v)
|
|
25 isa=isa+1
|
|
!
|
|
end do
|
|
end do
|
|
!
|
|
do ir=1,nnr
|
|
rhor(ir,isup)=rhor(ir,isup)+DBLE(v(ir))
|
|
rhor(ir,isdw)=rhor(ir,isdw)+AIMAG(v(ir))
|
|
end do
|
|
!
|
|
if(iprsta.gt.2) then
|
|
ca = SUM(v)
|
|
call reduce(2,ca)
|
|
WRITE( stdout,'(a,2f12.8)') 'rhov:in n_v ',omega*ca/(nr1*nr2*nr3)
|
|
endif
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
if(iprsta.gt.2) then
|
|
WRITE( stdout,*) 'rhov: smooth up',omega*rhog(1,isup)
|
|
WRITE( stdout,*) 'rhov: smooth dw',omega*rhog(1,isdw)
|
|
WRITE( stdout,*) 'rhov: vander up',omega*DBLE(v(1))
|
|
WRITE( stdout,*) 'rhov: vander dw',omega*AIMAG(v(1))
|
|
WRITE( stdout,*) 'rhov: all up', &
|
|
& omega*(rhog(1,isup)+DBLE(v(1)))
|
|
WRITE( stdout,*) 'rhov: all dw', &
|
|
& omega*(rhog(1,isdw)+AIMAG(v(1)))
|
|
endif
|
|
!
|
|
do ig=1,ng
|
|
fp= v(np(ig)) + v(nm(ig))
|
|
fm= v(np(ig)) - v(nm(ig))
|
|
rhog(ig,isup)=rhog(ig,isup) + 0.5*CMPLX(DBLE(fp),AIMAG(fm))
|
|
rhog(ig,isdw)=rhog(ig,isdw) + 0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
!
|
|
if(iprsta.gt.2) WRITE( stdout,'(a,2f12.8)') &
|
|
& ' rhov: n_v(g=0) up = ',omega*DBLE (rhog(1,isup))
|
|
if(iprsta.gt.2) WRITE( stdout,'(a,2f12.8)') &
|
|
& ' rhov: n_v(g=0) down = ',omega*DBLE(rhog(1,isdw))
|
|
!
|
|
endif
|
|
|
|
deallocate(qgbt)
|
|
deallocate( v )
|
|
deallocate( qv )
|
|
|
|
call stop_clock( 'rhov' )
|
|
!
|
|
return
|
|
end subroutine rhov
|
|
!
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine s_wfc(n_atomic_wfc,becwfc,betae,wfc,swfc)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! input: wfc, becwfc=<wfc|beta>, betae=|beta>
|
|
! output: swfc=S|wfc>
|
|
!
|
|
use ions_base, only: na
|
|
use cvan, only: nvb, ish
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus, qq
|
|
use uspp_param, only: nh
|
|
use gvecw, only: ngw
|
|
!use parm
|
|
use constants, only: pi, fpi
|
|
implicit none
|
|
! input
|
|
integer, intent(in) :: n_atomic_wfc
|
|
complex(8), intent(in) :: betae(ngw,nhsa), &
|
|
& wfc(ngw,n_atomic_wfc)
|
|
real(8), intent(in) :: becwfc(nhsa,n_atomic_wfc)
|
|
! output
|
|
complex(8), intent(out):: swfc(ngw,n_atomic_wfc)
|
|
! local
|
|
integer is, iv, jv, ia, inl, jnl, i
|
|
real(8) qtemp(nhsavb,n_atomic_wfc)
|
|
!
|
|
swfc=0.d0
|
|
!
|
|
if (nvb.gt.0) then
|
|
qtemp=0.d0
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
do i=1,n_atomic_wfc
|
|
qtemp(inl,i) = qtemp(inl,i) + &
|
|
& qq(iv,jv,is)*becwfc(jnl,i)
|
|
end do
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
call MXMA (betae,1,2*ngw,qtemp,1,nhsavb,swfc,1, &
|
|
& 2*ngw,2*ngw,nhsavb,n_atomic_wfc)
|
|
end if
|
|
!
|
|
swfc=swfc+wfc
|
|
!
|
|
return
|
|
end subroutine s_wfc
|
|
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine sigset(cp,becp,qbecp,nss,ist,sig)
|
|
!-----------------------------------------------------------------------
|
|
! input: cp (non-orthonormal), becp, qbecp
|
|
! computes the matrix
|
|
! sig = 1 - a , a = <cp|s|cp> = <cp|cp> + sum q_ij <cp|i><j|cp>
|
|
! where s=s(r(t+dt))
|
|
! routine makes use of c(-q)=c*(q)
|
|
!
|
|
use parameters, only: natx, nsx
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus
|
|
use cvan, only : nvb
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
!
|
|
implicit none
|
|
!
|
|
integer nss, ist
|
|
complex(8) cp(ngw,n)
|
|
real(8) becp(nhsa,n), qbecp(nhsa,n), sig(nx,nx)
|
|
!
|
|
integer i, j
|
|
real(8) tmp1(nx,nx) ! automatic array
|
|
!
|
|
sig = 0.d0
|
|
call MXMA(cp(1,ist),2*ngw,1,cp(1,ist),1,2*ngw, &
|
|
& sig,1,nx,nss,2*ngw,nss)
|
|
!
|
|
! q >= 0 components with weight 2.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
sig(i,j)=-2.*sig(i,j)
|
|
end do
|
|
end do
|
|
if (gstart == 2) then
|
|
!
|
|
! q = 0 components has weight 1.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
sig(i,j) = sig(i,j) + &
|
|
& DBLE(cp(1,i+ist-1))*DBLE(cp(1,j+ist-1))
|
|
end do
|
|
end do
|
|
end if
|
|
call reduce(nx*nss,sig)
|
|
do i=1,nss
|
|
sig(i,i) = sig(i,i)+1.
|
|
end do
|
|
!
|
|
if(nvb.gt.0)then
|
|
tmp1 = 0.d0
|
|
!
|
|
call MXMA(becp(1,ist),nhsa,1,qbecp(1,ist),1,nhsa, &
|
|
& tmp1,1,nx,nss,nhsavb,nss)
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
sig(i,j)=sig(i,j)-tmp1(i,j)
|
|
end do
|
|
end do
|
|
endif
|
|
!
|
|
return
|
|
end subroutine sigset
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine spinsq (c,bec,rhor)
|
|
!-----------------------------------------------------------------------
|
|
!
|
|
! estimate of <S^2>=s(s+1) in two different ways.
|
|
! 1) using as many-body wavefunction a single Slater determinant
|
|
! constructed with Kohn-Sham orbitals:
|
|
!
|
|
! <S^2> = (Nup-Ndw)/2 * (Nup-Ndw)/2+1) + Ndw -
|
|
! \sum_up\sum_dw < psi_up | psi_dw >
|
|
!
|
|
! where Nup, Ndw = number of up and down states, the sum is over
|
|
! occupied states. Not suitable for fractionary occupancy.
|
|
! In the ultrasoft scheme (c is the smooth part of \psi):
|
|
!
|
|
! < psi_up | psi_dw > = \sum_G c*_up(G) c_dw(G) +
|
|
! \int Q_ij <c_up|beta_i><beta_j|c_dw>
|
|
!
|
|
! This is the usual formula, unsuitable for fractionary occupancy.
|
|
! 2) using the "LSD model" of Wang, Becke, Smith, JCP 102, 3477 (1995):
|
|
!
|
|
! <S^2> = (Nup-Ndw)/2 * (Nup-Ndw)/2+1) + Ndw -
|
|
! \int max(rhoup(r),rhodw(r)) dr
|
|
!
|
|
! Requires on input: c=psi, bec=<c|beta>, rhoup(r), rhodw(r)
|
|
! Assumes real psi, with only half G vectors.
|
|
!
|
|
use electrons_base, only: nx => nbspx, n => nbsp, iupdwn, nupdwn, f, nel, nspin
|
|
use io_global, only: stdout
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nnr => nnrx
|
|
use cell_base, only: omega
|
|
use cvan, only: nvb, ish
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus, qq
|
|
use uspp_param, only: nh
|
|
use ions_base, only: na
|
|
!
|
|
implicit none
|
|
! input
|
|
real(8) bec(nhsa,n), rhor(nnr,nspin)
|
|
complex(8) c(ngw,nx)
|
|
! local variables
|
|
integer nup, ndw, ir, i, j, jj, ig, ia, is, iv, jv, inl, jnl
|
|
real(8) spin0, spin1, spin2, fup, fdw
|
|
real(8), allocatable:: overlap(:,:), temp(:)
|
|
logical frac
|
|
!
|
|
!
|
|
if (nspin.eq.1) return
|
|
!
|
|
! find spin-up and spin-down states
|
|
!
|
|
fup = 0.0
|
|
do i=iupdwn(1),nupdwn(1)
|
|
fup = fup + f(i)
|
|
end do
|
|
nup = nint(fup)
|
|
ndw = nel(1)+nel(2) - nup
|
|
!
|
|
! paranoid checks
|
|
!
|
|
frac= abs(fup-nup).gt.1.0e-6
|
|
fup = 0.0
|
|
do i=1,nup
|
|
fup = fup + f(i)
|
|
end do
|
|
frac=frac.or.abs(fup-nup).gt.1.0e-6
|
|
fdw = 0.0
|
|
do j=iupdwn(2),iupdwn(2)-1+ndw
|
|
fdw = fdw + f(j)
|
|
end do
|
|
frac=frac.or.abs(fdw-ndw).gt.1.0e-6
|
|
!
|
|
spin0 = abs(fup-fdw)/2.d0 * ( abs(fup-fdw)/2.d0 + 1.d0 ) + fdw
|
|
!
|
|
! Becke's formula for spin polarization
|
|
!
|
|
spin1 = 0.0
|
|
do ir=1,nnr
|
|
spin1 = spin1 - min(rhor(ir,1),rhor(ir,2))
|
|
end do
|
|
call reduce(1,spin1)
|
|
spin1 = spin0 + omega/(nr1*nr2*nr3)*spin1
|
|
if (frac) then
|
|
WRITE( stdout,'(/'' Spin contamination: s(s+1)='',f5.2,'' (Becke) '',&
|
|
& f5.2,'' (expected)'')') &
|
|
& spin1, abs(fup-fdw)/2.d0*(abs(fup-fdw)/2.d0+1.d0)
|
|
return
|
|
end if
|
|
!
|
|
! Slater formula, smooth contribution to < psi_up | psi_dw >
|
|
!
|
|
allocate (overlap(nup,ndw))
|
|
allocate (temp(ngw))
|
|
do j=1,ndw
|
|
jj=j+iupdwn(2)-1
|
|
do i=1,nup
|
|
overlap(i,j)=0.d0
|
|
do ig=1,ngw
|
|
temp(ig)=DBLE(CONJG(c(ig,i))*c(ig,jj))
|
|
end do
|
|
overlap(i,j) = 2.d0*SUM(temp)
|
|
if (gstart == 2) overlap(i,j) = overlap(i,j) - temp(1)
|
|
end do
|
|
end do
|
|
deallocate (temp)
|
|
call reduce(nup*ndw,overlap)
|
|
do j=1,ndw
|
|
jj=j+iupdwn(2)-1
|
|
do i=1,nup
|
|
!
|
|
! vanderbilt contribution to < psi_up | psi_dw >
|
|
!
|
|
do is=1,nvb
|
|
do iv=1,nh(is)
|
|
do jv=1,nh(is)
|
|
if(abs(qq(iv,jv,is)).gt.1.e-5) then
|
|
do ia=1,na(is)
|
|
inl=ish(is)+(iv-1)*na(is)+ia
|
|
jnl=ish(is)+(jv-1)*na(is)+ia
|
|
overlap(i,j) = overlap(i,j) + &
|
|
& qq(iv,jv,is)*bec(inl,i)*bec(jnl,jj)
|
|
end do
|
|
endif
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
spin2 = spin0
|
|
do j=1,ndw
|
|
do i=1,nup
|
|
spin2 = spin2 - overlap(i,j)**2
|
|
end do
|
|
end do
|
|
!
|
|
deallocate (overlap)
|
|
!
|
|
WRITE( stdout,'(/" Spin contamination: s(s+1)=",f5.2," (Slater) ", &
|
|
& f5.2," (Becke) ",f5.2," (expected)")') &
|
|
& spin2,spin1, abs(fup-fdw)/2.d0*(abs(fup-fdw)/2.d0+1.d0)
|
|
!
|
|
return
|
|
end subroutine spinsq
|
|
!-------------------------------------------------------------------------
|
|
subroutine tauset(phi,bephi,qbephi,nss,ist,tau)
|
|
!-----------------------------------------------------------------------
|
|
! input: phi
|
|
! computes the matrix
|
|
! tau = <s'c0|s|s'c0> = <phi|s|phi>, where |phi> = s'|c0>
|
|
! where s=s(r(t+dt)) and s'=s(r(t))
|
|
! routine makes use of c(-q)=c*(q)
|
|
!
|
|
use parameters, only: nsx, natx
|
|
use cvan, only: nvb
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use gvecw, only: ngw
|
|
use reciprocal_vectors, only: gstart
|
|
!
|
|
implicit none
|
|
integer nss, ist
|
|
complex(8) phi(ngw,n)
|
|
real(8) bephi(nhsa,n), qbephi(nhsa,n), tau(nx,nx)
|
|
integer i, j
|
|
real(8) tmp1(nx,nx) ! automatic array
|
|
!
|
|
tau = 0.d0
|
|
call MXMA(phi(1,ist),2*ngw,1,phi(1,ist),1,2*ngw, &
|
|
& tau,1,nx,nss,2*ngw,nss)
|
|
!
|
|
! q >= 0 components with weight 2.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
tau(i,j)=2.*tau(i,j)
|
|
end do
|
|
end do
|
|
if (gstart == 2) then
|
|
!
|
|
! q = 0 components has weight 1.0
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
tau(i,j) = tau(i,j) - &
|
|
& DBLE(phi(1,i+ist-1))*DBLE(phi(1,j+ist-1))
|
|
end do
|
|
end do
|
|
end if
|
|
call reduce(nx*nss,tau)
|
|
!
|
|
if(nvb.gt.0)then
|
|
tmp1 = 0.d0
|
|
!
|
|
call MXMA(bephi(1,ist),nhsa,1,qbephi(1,ist),1,nhsa, &
|
|
& tmp1,1,nx,nss,nhsavb,nss)
|
|
!
|
|
do j=1,nss
|
|
do i=1,nss
|
|
tau(i,j)=tau(i,j)+tmp1(i,j)
|
|
end do
|
|
end do
|
|
endif
|
|
!
|
|
return
|
|
end subroutine tauset
|
|
!
|
|
!-------------------------------------------------------------------------
|
|
subroutine updatc(ccc,x0,phi,bephi,becp,bec,cp)
|
|
!-----------------------------------------------------------------------
|
|
! input ccc : dt**2/emass (unchanged in output)
|
|
! input x0 : converged lambdas from ortho-loop (unchanged in output)
|
|
! input cp : non-orthonormal cp=c0+dh/dc*ccc
|
|
! input bec : <cp|beta_i>
|
|
! input phi
|
|
! output cp : orthonormal cp=cp+lambda*phi
|
|
! output bec: bec=becp+lambda*bephi
|
|
!
|
|
use ions_base, only: nsp, na
|
|
use io_global, only: stdout
|
|
use cvan, only: nvb, ish
|
|
use uspp, only: nhsa => nkb, nhsavb=>nkbus
|
|
use uspp_param, only: nh
|
|
use gvecw, only: ngw
|
|
use electrons_base, only: nx => nbspx, n => nbsp
|
|
use control_flags, only: iprint, iprsta
|
|
!
|
|
implicit none
|
|
!
|
|
complex(8) cp(ngw,n), phi(ngw,n)
|
|
real(8) bec(nhsa,n), x0(nx,nx), ccc
|
|
real(8) bephi(nhsa,n), becp(nhsa,n)
|
|
! local variables
|
|
integer i, j, ig, is, iv, ia, inl
|
|
real(8) wtemp(n,nhsa) ! automatic array
|
|
complex(8), allocatable :: wrk2(:,:)
|
|
!
|
|
! lagrange multipliers
|
|
!
|
|
call start_clock( 'updatc' )
|
|
|
|
allocate( wrk2( ngw, n ) )
|
|
|
|
wrk2 = (0.d0, 0.d0)
|
|
do j=1,n
|
|
call DSCAL(n,ccc,x0(1,j),1)
|
|
end do
|
|
!
|
|
! wrk2 = sum_m lambda_nm s(r(t+dt))|m>
|
|
!
|
|
call MXMA(phi,1,2*ngw,x0,nx,1,wrk2,1,2*ngw,2*ngw,n,n)
|
|
!
|
|
do i=1,n
|
|
do ig=1,ngw
|
|
cp(ig,i)=cp(ig,i)+wrk2(ig,i)
|
|
end do
|
|
end do
|
|
!
|
|
! updating of the <beta|c(n,g)>
|
|
!
|
|
! bec of vanderbilt species are updated
|
|
!
|
|
if(nvb.gt.0)then
|
|
call MXMA(x0,1,nx,bephi,nhsa,1,wtemp,1,n,n,n,nhsavb)
|
|
!
|
|
do i=1,n
|
|
do inl=1,nhsavb
|
|
bec(inl,i)=wtemp(i,inl)+becp(inl,i)
|
|
end do
|
|
end do
|
|
endif
|
|
!
|
|
if (iprsta.gt.2) then
|
|
WRITE( stdout,*)
|
|
do is=1,nsp
|
|
if(nsp.gt.1) then
|
|
WRITE( stdout,'(33x,a,i4)') ' updatc: bec (is)',is
|
|
WRITE( stdout,'(8f9.4)') &
|
|
& ((bec(ish(is)+(iv-1)*na(is)+1,i),iv=1,nh(is)),i=1,n)
|
|
else
|
|
do ia=1,na(is)
|
|
WRITE( stdout,'(33x,a,i4)') ' updatc: bec (ia)',ia
|
|
WRITE( stdout,'(8f9.4)') &
|
|
& ((bec(ish(is)+(iv-1)*na(is)+ia,i),iv=1,nh(is)),i=1,n)
|
|
end do
|
|
end if
|
|
WRITE( stdout,*)
|
|
end do
|
|
endif
|
|
!
|
|
do j=1,n
|
|
call DSCAL(n,1.0/ccc,x0(1,j),1)
|
|
end do
|
|
|
|
deallocate( wrk2 )
|
|
!
|
|
call stop_clock( 'updatc' )
|
|
!
|
|
return
|
|
end subroutine updatc
|
|
!
|
|
!-----------------------------------------------------------------------
|
|
subroutine vofrho(nfi,rhor,rhog,rhos,rhoc,tfirst,tlast, &
|
|
& ei1,ei2,ei3,irb,eigrb,sfac,tau0,fion)
|
|
!-----------------------------------------------------------------------
|
|
! computes: the one-particle potential v in real space,
|
|
! the total energy etot,
|
|
! the forces fion acting on the ions,
|
|
! the derivative of total energy to cell parameters h
|
|
! rhor input : electronic charge on dense real space grid
|
|
! (plus core charge if present)
|
|
! rhog input : electronic charge in g space (up to density cutoff)
|
|
! rhos input : electronic charge on smooth real space grid
|
|
! rhor output: total potential on dense real space grid
|
|
! rhos output: total potential on smooth real space grid
|
|
!
|
|
use kinds, only: dp
|
|
use control_flags, only: iprint, tvlocw, iprsta, thdyn, tpre, tfor, tprnfor
|
|
use io_global, only: stdout
|
|
use parameters, only: natx, nsx
|
|
use ions_base, only: nas => nax, nsp, na, nat
|
|
use gvecs
|
|
use gvecp, only: ng => ngm
|
|
use cell_base, only: omega
|
|
use cell_base, only: a1, a2, a3, tpiba2
|
|
use reciprocal_vectors, only: gstart, g
|
|
use recvecs_indexes, only: np, nm
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nr3x, nnr => nnrx
|
|
use smooth_grid_dimensions, only: nr1s, nr2s, nr3s, &
|
|
nr1sx, nr2sx, nr3sx, nnrsx
|
|
use electrons_base, only: nspin
|
|
use constants, only: pi, fpi
|
|
use energies, only: etot, eself, enl, ekin, epseu, esr, eht, exc
|
|
use local_pseudo, only: vps, rhops
|
|
use core, only: nlcc_any
|
|
use gvecb
|
|
use dener
|
|
use derho
|
|
use mp, only: mp_sum
|
|
use funct, only: ismeta
|
|
!
|
|
implicit none
|
|
!
|
|
logical tlast,tfirst
|
|
integer nfi
|
|
real(8) rhor(nnr,nspin), rhos(nnrsx,nspin), fion(3,natx)
|
|
real(8) rhoc(nnr), tau0(3,natx)
|
|
complex(8) ei1(-nr1:nr1,nat), ei2(-nr2:nr2,nat), &
|
|
& ei3(-nr3:nr3,nat), eigrb(ngb,nat), &
|
|
& rhog(ng,nspin), sfac(ngs,nsp)
|
|
!
|
|
integer irb(3,nat), iss, isup, isdw, ig, ir,i,j,k,is, ia
|
|
real(8) fion1(3,natx), vave, ebac, wz, eh
|
|
complex(8) fp, fm, ci
|
|
complex(8), allocatable :: v(:), vs(:)
|
|
complex(8), allocatable :: rhotmp(:), vtemp(:), drhotmp(:,:,:)
|
|
!
|
|
call start_clock( 'vofrho' )
|
|
ci=(0.,1.)
|
|
!
|
|
! wz = factor for g.neq.0 because of c*(g)=c(-g)
|
|
!
|
|
wz = 2.0
|
|
allocate( v( nnr ) )
|
|
allocate( vs( nnrsx ) )
|
|
allocate(vtemp(ng))
|
|
allocate(rhotmp(ng))
|
|
if (tpre) allocate(drhotmp(ng,3,3))
|
|
!
|
|
! first routine in which fion is calculated: annihilation
|
|
!
|
|
fion =0.d0
|
|
fion1=0.d0
|
|
!
|
|
! ===================================================================
|
|
! forces on ions, ionic term in real space
|
|
! -------------------------------------------------------------------
|
|
if( tprnfor .or. tfor .or. tfirst .or. tpre ) then
|
|
call force_ion(tau0,esr,fion,dsr)
|
|
end if
|
|
!
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ig=1,ng
|
|
rhotmp(ig)=rhog(ig,iss)
|
|
end do
|
|
if(tpre)then
|
|
do j=1,3
|
|
do i=1,3
|
|
do ig=1,ng
|
|
drhotmp(ig,i,j)=drhog(ig,iss,i,j)
|
|
enddo
|
|
enddo
|
|
enddo
|
|
endif
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ng
|
|
rhotmp(ig)=rhog(ig,isup)+rhog(ig,isdw)
|
|
end do
|
|
if(tpre)then
|
|
do i=1,3
|
|
do j=1,3
|
|
do ig=1,ng
|
|
drhotmp(ig,i,j) = drhog(ig,isup,i,j) + &
|
|
& drhog(ig,isdw,i,j)
|
|
enddo
|
|
enddo
|
|
enddo
|
|
endif
|
|
end if
|
|
! ===================================================================
|
|
! calculation local potential energy
|
|
! -------------------------------------------------------------------
|
|
vtemp=(0.,0.)
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
vtemp(ig)=vtemp(ig)+CONJG(rhotmp(ig))*sfac(ig,is)*vps(ig,is)
|
|
end do
|
|
end do
|
|
!
|
|
epseu=wz*DBLE(SUM(vtemp))
|
|
if (gstart == 2) epseu=epseu-vtemp(1)
|
|
call reduce(1,epseu)
|
|
epseu=epseu*omega
|
|
!
|
|
if(tpre) call denps(rhotmp,drhotmp,sfac,vtemp,dps)
|
|
!
|
|
! ===================================================================
|
|
! calculation hartree energy
|
|
! -------------------------------------------------------------------
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
rhotmp(ig)=rhotmp(ig)+sfac(ig,is)*rhops(ig,is)
|
|
end do
|
|
end do
|
|
if (gstart == 2) vtemp(1)=0.0
|
|
do ig=gstart,ng
|
|
vtemp(ig)=CONJG(rhotmp(ig))*rhotmp(ig)/g(ig)
|
|
end do
|
|
!
|
|
eh=DBLE(SUM(vtemp))*wz*0.5*fpi/tpiba2
|
|
call reduce(1,eh)
|
|
if(tpre) call denh(rhotmp,drhotmp,sfac,vtemp,eh,dh)
|
|
if(tpre) deallocate(drhotmp)
|
|
! ===================================================================
|
|
! forces on ions, ionic term in reciprocal space
|
|
! -------------------------------------------------------------------
|
|
if( tprnfor .or. tfor .or. tpre) &
|
|
& call force_ps(rhotmp,rhog,vtemp,ei1,ei2,ei3,fion1)
|
|
! ===================================================================
|
|
! calculation hartree + local pseudo potential
|
|
! -------------------------------------------------------------------
|
|
!
|
|
if (gstart == 2) vtemp(1)=(0.,0.)
|
|
do ig=gstart,ng
|
|
vtemp(ig)=rhotmp(ig)*fpi/(tpiba2*g(ig))
|
|
end do
|
|
!
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
vtemp(ig)=vtemp(ig)+sfac(ig,is)*vps(ig,is)
|
|
end do
|
|
end do
|
|
!
|
|
! vtemp = v_loc(g) + v_h(g)
|
|
!
|
|
! ===================================================================
|
|
! calculation exchange and correlation energy and potential
|
|
! -------------------------------------------------------------------
|
|
if (nlcc_any) call add_cc(rhoc,rhog,rhor)
|
|
!
|
|
call exch_corr_h(nspin,rhog,rhor,rhoc,sfac,exc,dxc)
|
|
!
|
|
! rhor contains the xc potential in r-space
|
|
!
|
|
! ===================================================================
|
|
! fourier transform of xc potential to g-space (dense grid)
|
|
! -------------------------------------------------------------------
|
|
!
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ir=1,nnr
|
|
v(ir)=CMPLX(rhor(ir,iss),0.d0)
|
|
end do
|
|
!
|
|
! v_xc(r) --> v_xc(g)
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ig=1,ng
|
|
rhog(ig,iss)=vtemp(ig)+v(np(ig))
|
|
end do
|
|
!
|
|
! v_tot(g) = (v_tot(g) - v_xc(g)) +v_xc(g)
|
|
! rhog contains the total potential in g-space
|
|
!
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ir=1,nnr
|
|
v(ir)=CMPLX(rhor(ir,isup),rhor(ir,isdw))
|
|
end do
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ig=1,ng
|
|
fp=v(np(ig))+v(nm(ig))
|
|
fm=v(np(ig))-v(nm(ig))
|
|
rhog(ig,isup)=vtemp(ig)+0.5*CMPLX( DBLE(fp),AIMAG(fm))
|
|
rhog(ig,isdw)=vtemp(ig)+0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
endif
|
|
!
|
|
! rhog contains now the total (local+Hartree+xc) potential in g-space
|
|
!
|
|
if( tprnfor .or. tfor ) then
|
|
|
|
if (nlcc_any) call force_cc(irb,eigrb,rhor,fion1)
|
|
|
|
call mp_sum( fion1 )
|
|
!
|
|
! add g-space ionic and core correction contributions to fion
|
|
!
|
|
fion = fion + fion1
|
|
|
|
end if
|
|
! ===================================================================
|
|
! fourier transform of total potential to r-space (dense grid)
|
|
! -------------------------------------------------------------------
|
|
v(:) = (0.d0, 0.d0)
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ig=1,ng
|
|
v(np(ig))=rhog(ig,iss)
|
|
v(nm(ig))=CONJG(rhog(ig,iss))
|
|
end do
|
|
!
|
|
! v(g) --> v(r)
|
|
!
|
|
call invfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ir=1,nnr
|
|
rhor(ir,iss)=DBLE(v(ir))
|
|
end do
|
|
!
|
|
! calculation of average potential
|
|
!
|
|
vave=SUM(rhor(:,iss))/DBLE(nr1*nr2*nr3)
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ng
|
|
v(np(ig))=rhog(ig,isup)+ci*rhog(ig,isdw)
|
|
v(nm(ig))=CONJG(rhog(ig,isup)) +ci*conjg(rhog(ig,isdw))
|
|
end do
|
|
!
|
|
call invfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ir=1,nnr
|
|
rhor(ir,isup)= DBLE(v(ir))
|
|
rhor(ir,isdw)=AIMAG(v(ir))
|
|
end do
|
|
!
|
|
! calculation of average potential
|
|
!
|
|
vave=(SUM(rhor(:,isup))+SUM(rhor(:,isdw))) &
|
|
& /2.0/DBLE(nr1*nr2*nr3)
|
|
endif
|
|
call reduce(1,vave)
|
|
! ===================================================================
|
|
! fourier transform of total potential to r-space (smooth grid)
|
|
! -------------------------------------------------------------------
|
|
vs (:) = (0.d0, 0.d0)
|
|
if(nspin.eq.1)then
|
|
iss=1
|
|
do ig=1,ngs
|
|
vs(nms(ig))=CONJG(rhog(ig,iss))
|
|
vs(nps(ig))=rhog(ig,iss)
|
|
end do
|
|
!
|
|
call ivffts(vs,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
!
|
|
do ir=1,nnrsx
|
|
rhos(ir,iss)=DBLE(vs(ir))
|
|
end do
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ngs
|
|
vs(nps(ig))=rhog(ig,isup)+ci*rhog(ig,isdw)
|
|
vs(nms(ig))=CONJG(rhog(ig,isup)) +ci*conjg(rhog(ig,isdw))
|
|
end do
|
|
call ivffts(vs,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
do ir=1,nnrsx
|
|
rhos(ir,isup)= DBLE(vs(ir))
|
|
rhos(ir,isdw)=AIMAG(vs(ir))
|
|
end do
|
|
endif
|
|
if(ismeta) call vofrho_meta(v,vs) !METAGGA
|
|
ebac=0.0
|
|
!
|
|
eht=eh*omega+esr-eself
|
|
!
|
|
! etot is the total energy ; ekin, enl were calculated in rhoofr
|
|
!
|
|
etot=ekin+eht+epseu+enl+exc+ebac
|
|
if(tpre) detot=dekin+dh+dps+denl+dxc+dsr
|
|
!
|
|
if(tvlocw.and.tlast)then
|
|
#ifdef __PARA
|
|
call write_rho(46,nspin,rhor)
|
|
#else
|
|
write(46) ((rhor(ir,iss),ir=1,nnr),iss=1,nspin)
|
|
#endif
|
|
endif
|
|
!
|
|
deallocate(rhotmp)
|
|
deallocate(vtemp)
|
|
deallocate( v )
|
|
deallocate( vs )
|
|
!
|
|
!
|
|
call stop_clock( 'vofrho' )
|
|
|
|
if((nfi.eq.0).or.tfirst.or.tlast) goto 999
|
|
if(mod(nfi-1,iprint).ne.0 ) return
|
|
!
|
|
999 if ( tpre ) then
|
|
if( iprsta >= 2 ) then
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "From vofrho:"
|
|
WRITE( stdout,*) "cell parameters h"
|
|
WRITE( stdout,5555) (a1(i),a2(i),a3(i),i=1,3)
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "derivative of e(tot)"
|
|
WRITE( stdout,5555) ((detot(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "derivative of e(kin)"
|
|
WRITE( stdout,5555) ((dekin(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(electrostatic)"
|
|
WRITE( stdout,5555) (((dh(i,j)+dsr(i,j)),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(h)"
|
|
WRITE( stdout,5555) ((dh(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(sr)"
|
|
WRITE( stdout,5555) ((dsr(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(ps)"
|
|
WRITE( stdout,5555) ((dps(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(nl)"
|
|
WRITE( stdout,5555) ((denl(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(xc)"
|
|
WRITE( stdout,5555) ((dxc(i,j),j=1,3),i=1,3)
|
|
endif
|
|
endif
|
|
5555 format(1x,f12.5,1x,f12.5,1x,f12.5/ &
|
|
& 1x,f12.5,1x,f12.5,1x,f12.5/ &
|
|
& 1x,f12.5,1x,f12.5,1x,f12.5//)
|
|
!
|
|
return
|
|
end subroutine vofrho
|
|
|
|
!
|
|
!----------------------------------------------------------------------
|
|
subroutine checkrho(nnr,nspin,rhor,rmin,rmax,rsum,rnegsum)
|
|
!----------------------------------------------------------------------
|
|
!
|
|
! check \int rho(r)dr and the negative part of rho
|
|
!
|
|
implicit none
|
|
integer nnr, nspin
|
|
real(8) rhor(nnr,nspin), rmin, rmax, rsum, rnegsum
|
|
!
|
|
real(8) roe
|
|
integer ir, iss
|
|
!
|
|
rsum =0.0
|
|
rnegsum=0.0
|
|
rmin =100.
|
|
rmax =0.0
|
|
do iss=1,nspin
|
|
do ir=1,nnr
|
|
roe=rhor(ir,iss)
|
|
rsum=rsum+roe
|
|
if (roe.lt.0.0) rnegsum=rnegsum+roe
|
|
rmax=max(rmax,roe)
|
|
rmin=min(rmin,roe)
|
|
end do
|
|
end do
|
|
call reduce(1,rsum)
|
|
call reduce(1,rnegsum)
|
|
return
|
|
end subroutine checkrho
|
|
!______________________________________________________________________
|
|
|
|
|
|
!-----------------------------------------------------------------------
|
|
subroutine vofrho_wf(nfi,rhor,rhog,rhos,rhoc,tfirst,tlast, &
|
|
& ei1,ei2,ei3,irb,eigrb,sfac,tau0,fion)
|
|
!-----------------------------------------------------------------------
|
|
! computes: the one-particle potential v in real space,
|
|
! the total energy etot,
|
|
! the forces fion acting on the ions,
|
|
! the derivative of total energy to cell parameters h
|
|
! rhor input : electronic charge on dense real space grid
|
|
! (plus core charge if present)
|
|
! rhog input : electronic charge in g space (up to density cutoff)
|
|
! rhos input : electronic charge on smooth real space grid
|
|
! rhor output: total potential on dense real space grid
|
|
! rhos output: total potential on smooth real space grid
|
|
!
|
|
use kinds, only: dp
|
|
use control_flags, only: iprint, tvlocw, iprsta, thdyn, tpre, tfor, tprnfor
|
|
use io_global, only: stdout
|
|
use parameters, only: natx, nsx
|
|
use ions_base, only: nas => nax, nsp, na, nat
|
|
use gvecs
|
|
use cell_base, only: omega, tpiba2
|
|
use cell_base, only: a1, a2, a3, alat
|
|
use grid_dimensions, only: nr1, nr2, nr3, &
|
|
nr1x, nr2x, nr3x, nnr => nnrx
|
|
use smooth_grid_dimensions, only: nr1s, nr2s, nr3s, &
|
|
nr1sx, nr2sx, nr3sx, nnrsx
|
|
use electrons_base, only: nspin, qbac
|
|
use constants, only: pi, fpi
|
|
use energies, only: etot, eself, enl, ekin, epseu, esr, eht, exc, vave
|
|
use local_pseudo, only: rhops, vps
|
|
use core, only: nlcc_any
|
|
use gvecb
|
|
use atom, only: nlcc
|
|
use reciprocal_vectors, only: g
|
|
use reciprocal_vectors, only: ng0 => gstart
|
|
use recvecs_indexes, only: np, nm
|
|
use gvecp, only: ng => ngm
|
|
!
|
|
use dener
|
|
use derho
|
|
!
|
|
implicit none
|
|
!
|
|
logical tlast,tfirst
|
|
integer nfi
|
|
real(8) rhor(nnr,nspin), rhos(nnrsx,nspin), fion(3,natx)
|
|
real(8) rhoc(nnr), tau0(3,natx)
|
|
complex(8) ei1(-nr1:nr1,nat), ei2(-nr2:nr2,nat), &
|
|
& ei3(-nr3:nr3,nat), eigrb(ngb,nat), &
|
|
& rhog(ng,nspin), sfac(ngs,nsp)
|
|
!
|
|
integer irb(3,nat), iss, isup, isdw, ig, ir,i,j,k,is, ia
|
|
real(8) fion1(3,natx), ebac, wz, eh
|
|
complex(8) fp, fm, ci
|
|
complex(8), allocatable :: v(:), vs(:)
|
|
complex(8), allocatable:: rhotmp(:), vtemp(:), drhotmp(:,:,:)
|
|
|
|
! Makov Payne Variables
|
|
!
|
|
real(8) dipole,quadrupole
|
|
real(8) E_dip,E_quad,en1,en2
|
|
real(8), allocatable:: rhortot(:)
|
|
real(8) alpha
|
|
|
|
!
|
|
call start_clock( 'vofrho_wf' )
|
|
|
|
ci=(0.,1.)
|
|
!
|
|
! wz = factor for g.neq.0 because of c*(g)=c(-g)
|
|
!
|
|
wz = 2.0
|
|
allocate( v( nnr ) )
|
|
allocate( vs( nnrsx ) )
|
|
allocate(vtemp(ng))
|
|
! write(6,*) 'Allocated vtemp'
|
|
allocate(rhotmp(ng))
|
|
! write(6,*) 'Allocated rhotmp'
|
|
allocate(rhortot(nnr)) ! for Makov Payne
|
|
! write(6,*) 'Allocated rhortot'
|
|
if (tpre) allocate(drhotmp(ng,3,3))
|
|
! write(6,*) 'Allocated all'
|
|
!
|
|
! first routine in which fion is calculated: annihilation
|
|
!
|
|
fion =0.d0
|
|
fion1=0.d0
|
|
|
|
! write(6,*) 'Annihilation'
|
|
!
|
|
! ===================================================================
|
|
! forces on ions, ionic term in real space
|
|
! -------------------------------------------------------------------
|
|
if( tprnfor .or. tfor .or. tfirst .or. thdyn ) then
|
|
call force_ion(tau0,esr,fion,dsr)
|
|
end if
|
|
!
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ig=1,ng
|
|
rhotmp(ig)=rhog(ig,iss)
|
|
end do
|
|
if(tpre)then
|
|
do j=1,3
|
|
do i=1,3
|
|
do ig=1,ng
|
|
drhotmp(ig,i,j)=drhog(ig,iss,i,j)
|
|
enddo
|
|
enddo
|
|
enddo
|
|
endif
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ng
|
|
rhotmp(ig)=rhog(ig,isup)+rhog(ig,isdw)
|
|
end do
|
|
if(tpre)then
|
|
do i=1,3
|
|
do j=1,3
|
|
do ig=1,ng
|
|
drhotmp(ig,i,j) = drhog(ig,isup,i,j) + &
|
|
& drhog(ig,isdw,i,j)
|
|
enddo
|
|
enddo
|
|
enddo
|
|
endif
|
|
end if
|
|
! write(6,*) 'fion'
|
|
! ===================================================================
|
|
! calculation local potential energy
|
|
! -------------------------------------------------------------------
|
|
vtemp=(0.,0.)
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
vtemp(ig)=vtemp(ig)+CONJG(rhotmp(ig))*sfac(ig,is)*vps(ig,is)
|
|
end do
|
|
end do
|
|
!
|
|
epseu=wz*DBLE(SUM(vtemp(1:ngs)))
|
|
if (ng0.eq.2) epseu=epseu-vtemp(1)
|
|
call reduce(1,epseu)
|
|
epseu=epseu*omega
|
|
!
|
|
if(tpre) call denps(rhotmp,drhotmp,sfac,vtemp,dps)
|
|
|
|
! write(6,*) 'Local Energy'
|
|
!
|
|
! ===================================================================
|
|
! calculation hartree energy
|
|
! -------------------------------------------------------------------
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
rhotmp(ig)=rhotmp(ig)+sfac(ig,is)*rhops(ig,is)
|
|
end do
|
|
end do
|
|
if (ng0.eq.2) vtemp(1)=0.0
|
|
do ig=ng0,ng
|
|
vtemp(ig)=CONJG(rhotmp(ig))*rhotmp(ig)/g(ig)
|
|
end do
|
|
!
|
|
eh=DBLE(SUM(vtemp(1:ng)))*wz*0.5*fpi/tpiba2
|
|
call reduce(1,eh)
|
|
if(tpre) call denh(rhotmp,drhotmp,sfac,vtemp,eh,dh)
|
|
if(tpre) deallocate(drhotmp)
|
|
! write(6,*) 'Hartree Energy'
|
|
! ===================================================================
|
|
! forces on ions, ionic term in reciprocal space
|
|
! -------------------------------------------------------------------
|
|
if( tprnfor .or. tfor .or. thdyn) &
|
|
& call force_ps(rhotmp,rhog,vtemp,ei1,ei2,ei3,fion1)
|
|
! ===================================================================
|
|
! calculation hartree + local pseudo potential
|
|
! -------------------------------------------------------------------
|
|
!
|
|
if (ng0.eq.2) vtemp(1)=(0.,0.)
|
|
do ig=ng0,ng
|
|
vtemp(ig)=rhotmp(ig)*fpi/(tpiba2*g(ig))
|
|
end do
|
|
!
|
|
do is=1,nsp
|
|
do ig=1,ngs
|
|
vtemp(ig)=vtemp(ig)+sfac(ig,is)*vps(ig,is)
|
|
end do
|
|
end do
|
|
!
|
|
! vtemp = v_loc(g) + v_h(g)
|
|
!
|
|
! write(6,*) 'Hartree + Local'
|
|
! Makov-Payne corrections, by Filippo
|
|
!
|
|
if(tlast) then
|
|
! ===================================================================
|
|
! fourier transform of total density to r-space (dense grid)
|
|
! -------------------------------------------------------------------
|
|
v(:) = (0.d0, 0.d0)
|
|
do ig=1,ng
|
|
v(nm(ig))=CONJG(rhotmp(ig))
|
|
v(np(ig))=rhotmp(ig)
|
|
end do
|
|
!
|
|
! v(g) --> v(r)
|
|
!
|
|
call invfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ir=1,nnr
|
|
rhortot(ir)=DBLE(v(ir))
|
|
end do
|
|
!
|
|
call poles(rhortot,dipole,quadrupole)
|
|
!
|
|
! Madelung constant for cubic lattice (NaCl)
|
|
|
|
!
|
|
alpha=1.7476
|
|
!
|
|
en1=qbac**2.*alpha/(2.*alat)
|
|
en2=2.*pi*qbac*quadrupole/(3.*alat**3)
|
|
!
|
|
write (6,*) "en1: ", en1
|
|
write (6,*) "en2: ", en2
|
|
!
|
|
E_quad= en1 + en2
|
|
!
|
|
! The interaction energy of the background charge (minus the
|
|
! molecular charge) with itself on a lattice (Madelung energy).
|
|
! +
|
|
! The interaction energy of the background charge with the nuclear
|
|
! quadupole moment on a lattice, with reversed sign due to the fact
|
|
! that the electron density is assumed to be positive.
|
|
!
|
|
end if
|
|
! END of Makov-Payne corrections, written by Filippo
|
|
!
|
|
!
|
|
! ===================================================================
|
|
! calculation exchange and correlation energy and potential
|
|
! -------------------------------------------------------------------
|
|
if ( ANY( nlcc ) ) call add_cc(rhoc,rhog,rhor)
|
|
!
|
|
! write(6,*) 'add_cc'
|
|
|
|
call exch_corr_h(nspin,rhog,rhor,rhoc,sfac,exc,dxc)
|
|
!
|
|
! rhor contains the xc potential in r-space
|
|
|
|
! write(6,*) 'XC R Space'
|
|
!
|
|
! ===================================================================
|
|
! fourier transform of xc potential to g-space (dense grid)
|
|
! -------------------------------------------------------------------
|
|
!
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ir=1,nnr
|
|
v(ir)=CMPLX(rhor(ir,iss),0.d0)
|
|
end do
|
|
!
|
|
! v_xc(r) --> v_xc(g)
|
|
!
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ig=1,ng
|
|
rhog(ig,iss)=vtemp(ig)+v(np(ig))
|
|
end do
|
|
!
|
|
! v_tot(g) = (v_tot(g) - v_xc(g)) +v_xc(g)
|
|
! rhog contains the total potential in g-space
|
|
!
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ir=1,nnr
|
|
v(ir)=CMPLX(rhor(ir,isup),rhor(ir,isdw))
|
|
end do
|
|
call fwfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ig=1,ng
|
|
fp=v(np(ig))+v(nm(ig))
|
|
fm=v(np(ig))-v(nm(ig))
|
|
rhog(ig,isup)=vtemp(ig)+0.5*CMPLX( DBLE(fp),AIMAG(fm))
|
|
rhog(ig,isdw)=vtemp(ig)+0.5*CMPLX(AIMAG(fp),-DBLE(fm))
|
|
end do
|
|
endif
|
|
!
|
|
! rhog contains now the total (local+Hartree+xc) potential in g-space
|
|
!
|
|
! write(6,*) 'XC G-Space'
|
|
|
|
if( tprnfor .or. tfor ) then
|
|
if ( ANY( nlcc ) ) call force_cc(irb,eigrb,rhor,fion1)
|
|
call reduce(3*natx,fion1)
|
|
!
|
|
! add g-space ionic and core correction contributions to fion
|
|
!
|
|
fion = fion + fion1
|
|
end if
|
|
! ===================================================================
|
|
! fourier transform of total potential to r-space (dense grid)
|
|
! -------------------------------------------------------------------
|
|
v(:) = (0.d0, 0.d0)
|
|
if(nspin.eq.1) then
|
|
iss=1
|
|
do ig=1,ng
|
|
v(np(ig))=rhog(ig,iss)
|
|
v(nm(ig))=CONJG(rhog(ig,iss))
|
|
end do
|
|
!
|
|
! v(g) --> v(r)
|
|
!
|
|
call invfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
!
|
|
do ir=1,nnr
|
|
rhor(ir,iss)=DBLE(v(ir))
|
|
end do
|
|
!
|
|
! calculation of average potential
|
|
!
|
|
vave=SUM(rhor(1:nnr,iss))/DBLE(nr1*nr2*nr3)
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ng
|
|
v(np(ig))=rhog(ig,isup)+ci*rhog(ig,isdw)
|
|
v(nm(ig))=CONJG(rhog(ig,isup)) +ci*conjg(rhog(ig,isdw))
|
|
end do
|
|
!
|
|
call invfft(v,nr1,nr2,nr3,nr1x,nr2x,nr3x)
|
|
do ir=1,nnr
|
|
rhor(ir,isup)= DBLE(v(ir))
|
|
rhor(ir,isdw)=AIMAG(v(ir))
|
|
end do
|
|
|
|
! write(6,*) 'Average Potential'
|
|
!
|
|
! calculation of average potential
|
|
!
|
|
vave=(SUM(rhor(1:nnr,isup))+SUM(rhor(1:nnr,isdw))) &
|
|
& /2.0/DBLE(nr1*nr2*nr3)
|
|
endif
|
|
call reduce(1,vave)
|
|
! ===================================================================
|
|
! fourier transform of total potential to r-space (smooth grid)
|
|
! -------------------------------------------------------------------
|
|
vs (:) = (0.d0, 0.d0)
|
|
if(nspin.eq.1)then
|
|
iss=1
|
|
do ig=1,ngs
|
|
vs(nms(ig))=CONJG(rhog(ig,iss))
|
|
vs(nps(ig))=rhog(ig,iss)
|
|
end do
|
|
!
|
|
call ivffts(vs,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
!
|
|
do ir=1,nnrsx
|
|
rhos(ir,iss)=DBLE(vs(ir))
|
|
end do
|
|
else
|
|
isup=1
|
|
isdw=2
|
|
do ig=1,ngs
|
|
vs(nps(ig))=rhog(ig,isup)+ci*rhog(ig,isdw)
|
|
vs(nms(ig))=CONJG(rhog(ig,isup)) +ci*conjg(rhog(ig,isdw))
|
|
end do
|
|
call ivffts(vs,nr1s,nr2s,nr3s,nr1sx,nr2sx,nr3sx)
|
|
do ir=1,nnrsx
|
|
rhos(ir,isup)= DBLE(vs(ir))
|
|
rhos(ir,isdw)=AIMAG(vs(ir))
|
|
end do
|
|
endif
|
|
|
|
|
|
! write(6,*) 'Total Potential r-space'
|
|
|
|
ebac=0.0
|
|
!
|
|
eht=eh*omega+esr-eself
|
|
!
|
|
! etot is the total energy ; ekin, enl were calculated in rhoofr
|
|
!
|
|
etot=ekin+eht+epseu+enl+exc+ebac
|
|
if(tpre) detot=dekin+dh+dps+denl+dxc+dsr
|
|
|
|
if(tlast) then
|
|
write (6,*)'MAKOV-PAYNE CORRECTED TOTAL ENERGY',etot+E_quad
|
|
write (6,*)'THIS CORRECTION IS VALID ONLY FOR CUBIC LATTICES'
|
|
end if
|
|
|
|
|
|
!
|
|
if(tvlocw.and.tlast)then
|
|
#ifdef __PARA
|
|
call write_rho(46,nspin,rhor)
|
|
#else
|
|
write(46) ((rhor(ir,iss),ir=1,nnr),iss=1,nspin)
|
|
#endif
|
|
endif
|
|
!
|
|
deallocate(rhotmp)
|
|
deallocate(vtemp)
|
|
deallocate(rhortot) ! Makov Payne Variable - M.S
|
|
deallocate( v )
|
|
deallocate( vs )
|
|
|
|
! write(6,*) 'Deallocations'
|
|
!
|
|
!
|
|
call stop_clock( 'vofrho_wf' )
|
|
if((nfi.eq.0).or.tfirst.or.tlast) goto 999
|
|
if(mod(nfi-1,iprint).ne.0 ) return
|
|
!
|
|
999 WRITE( stdout,1) etot,ekin,eht,esr,eself,epseu,enl,exc,vave
|
|
1 format(//' total energy = ',f14.5,' a.u.'/ &
|
|
& ' kinetic energy = ',f14.5,' a.u.'/ &
|
|
& ' electrostatic energy = ',f14.5,' a.u.'/ &
|
|
& ' esr = ',f14.5,' a.u.'/ &
|
|
& ' eself = ',f14.5,' a.u.'/ &
|
|
& ' pseudopotential energy = ',f14.5,' a.u.'/ &
|
|
& ' n-l pseudopotential energy = ',f14.5,' a.u.'/ &
|
|
& ' exchange-correlation energy = ',f14.5,' a.u.'/ &
|
|
& ' average potential = ',f14.5,' a.u.'//)
|
|
!
|
|
if(tpre)then
|
|
if(tpre.and.iprsta.ge.2) then
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "From vofrho:"
|
|
WRITE( stdout,*) "cell parameters h"
|
|
WRITE( stdout,5555) (a1(i),a2(i),a3(i),i=1,3)
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "derivative of e(tot)"
|
|
WRITE( stdout,5555) ((detot(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*)
|
|
WRITE( stdout,*) "derivative of e(kin)"
|
|
WRITE( stdout,5555) ((dekin(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(electrostatic)"
|
|
WRITE( stdout,5555) (((dh(i,j)+dsr(i,j)),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(h)"
|
|
WRITE( stdout,5555) ((dh(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(sr)"
|
|
WRITE( stdout,5555) ((dsr(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(ps)"
|
|
WRITE( stdout,5555) ((dps(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(nl)"
|
|
WRITE( stdout,5555) ((denl(i,j),j=1,3),i=1,3)
|
|
WRITE( stdout,*) "derivative of e(xc)"
|
|
WRITE( stdout,5555) ((dxc(i,j),j=1,3),i=1,3)
|
|
endif
|
|
endif
|
|
5555 format(1x,f12.5,1x,f12.5,1x,f12.5/ &
|
|
& 1x,f12.5,1x,f12.5,1x,f12.5/ &
|
|
& 1x,f12.5,1x,f12.5,1x,f12.5//)
|
|
!
|
|
return
|
|
end subroutine vofrho_wf
|
|
|
|
!------------------------------------------------------------------------
|
|
subroutine poles(rhortot,dipole,quadrupole)
|
|
!------------------------------------------------------------------------
|
|
!
|
|
use para_mod
|
|
! use parm
|
|
use grid_dimensions, only : nr1, nr2, nr3, nr1x, nr2x, nr3x, nnr=> nnrx
|
|
use cell_base, only : a1, a2, a3, omega
|
|
use electrons_base, only: qbac
|
|
!
|
|
implicit none
|
|
real(8), parameter :: debye=1./0.39344, angs=1./0.52917726
|
|
!
|
|
real(8) dipole,quadrupole,mu(3),quad(6)
|
|
real(8) ax,ay,az,XG0,YG0,ZG0,X,Y,Z,D,s,rzero,x0,y0,z0
|
|
real(8) en1,en2, pass1, pass2, pass3
|
|
real(8) rhortot(nnr)
|
|
! real(8), allocatable:: x(:),y(:),z(:)
|
|
real(8), allocatable:: dip(:)
|
|
integer (4) ix,ir, i, j, k
|
|
!
|
|
allocate(dip(nnr))
|
|
|
|
! compute the dipole moment
|
|
!
|
|
ax=a1(1)
|
|
ay=a2(2)
|
|
az=a3(3)
|
|
!
|
|
XG0 = -ax/2.
|
|
YG0 = -ay/2.
|
|
ZG0 = -az/2.
|
|
pass1=ax/nr1
|
|
pass2=ax/nr2
|
|
pass3=ax/nr3
|
|
! pass1 = ax / (nr1-1)
|
|
! pass2 = ay / (nr2-1)
|
|
! pass3 = az / (nr3-1)
|
|
!
|
|
do ix=1,3
|
|
ir=1
|
|
!
|
|
do k = dfftp%ipp(me)+1, dfftp%ipp(me)+ dfftp%npp(me)
|
|
do j=1,nr2x
|
|
do i=1,nr1x
|
|
X=XG0+(i-1)*pass1
|
|
Y=YG0+(j-1)*pass2
|
|
Z=ZG0+(k-1)*pass3
|
|
if (ix.eq.1) D=X
|
|
if (ix.eq.2) D=Y
|
|
if (ix.eq.3) D=Z
|
|
dip(ir)=D*rhortot(ir)
|
|
ir=ir+1
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
mu(ix)=sum(dip(1:nnr))
|
|
!
|
|
end do !!!!!!! ix
|
|
!
|
|
call reduce(3,mu)
|
|
!
|
|
do ix=1,3
|
|
mu(ix)=mu(ix)*omega/DBLE(nr1*nr2*nr3)
|
|
end do
|
|
!
|
|
dipole=sqrt(mu(1)**2+mu(2)**2+mu(3)**2)
|
|
!
|
|
!
|
|
! compute the coordinates which put the dipole moment to zero
|
|
!
|
|
if (abs(qbac).gt.1.d-05) then
|
|
x0=mu(1)/abs(qbac)
|
|
y0=mu(2)/abs(qbac)
|
|
z0=mu(3)/abs(qbac)
|
|
rzero=x0**2+y0**2+z0**2
|
|
else
|
|
rzero=0.
|
|
end if
|
|
!
|
|
! compute the quadrupole moment
|
|
!
|
|
do ix=1,6
|
|
!
|
|
ir=1
|
|
do k=dfftp%ipp(me)+1, dfftp%ipp(me) + dfftp%npp(me)
|
|
do j=1,nr2x
|
|
do i=1,nr1x
|
|
!
|
|
X=XG0+(i-1)*pass1
|
|
Y=YG0+(j-1)*pass2
|
|
Z=ZG0+(k-1)*pass3
|
|
!
|
|
if (ix.eq.1) D=X*X
|
|
if (ix.eq.2) D=Y*Y
|
|
if (ix.eq.3) D=Z*Z
|
|
if (ix.eq.4) D=X*Y
|
|
if (ix.eq.5) D=X*Z
|
|
if (ix.eq.6) D=Y*Z
|
|
!
|
|
dip(ir)=D*rhortot(ir)
|
|
!
|
|
ir=ir+1
|
|
end do
|
|
end do
|
|
end do
|
|
!
|
|
quad(ix)=SUM(dip(1:nnr))
|
|
end do
|
|
!
|
|
call reduce(6,quad)
|
|
|
|
do ix=1,6
|
|
quad(ix)=quad(ix)*omega/DBLE(nr1*nr2*nr3)
|
|
end do
|
|
!
|
|
quadrupole=quad(1)+quad(2)+quad(3)-rzero*qbac
|
|
!
|
|
! only the diagonal elements contribute to the inetaction energy
|
|
! the term rzero*qbac is subtracted to zero the dipole moment
|
|
!
|
|
write (*,1001)(mu(ix),ix=1,3)
|
|
write (*,1002) dipole
|
|
write (*,*) ' '
|
|
write (*,1003)(quad(ix),ix=1,3)
|
|
write (*,1004)(quad(ix),ix=4,6)
|
|
write (*,1005) quadrupole,rzero*qbac
|
|
!
|
|
1001 format('DIPOLE XYZ-COMPONENTS (A.U.)',f10.4,2x,f10.4,2x,f10.4)
|
|
1002 format('DIPOLE MOMENT (A.U.)',f10.4)
|
|
1003 format('QUADRUPOLE XX-YY-ZZ COMPONENTS (A.U.)', &
|
|
&f9.4,2x,f9.4,2x,f9.4)
|
|
1004 format('QUADRUPOLE XY-XZ-YZ COMPONENTS (A.U.)', &
|
|
&f9.4,2x,f9.4,2x,f9.4)
|
|
1005 format('QUADRUPOLE MOMENT (A.U.)',2f9.4)
|
|
!
|
|
deallocate(dip)
|
|
!
|
|
return
|
|
end subroutine poles
|
|
|