mirror of https://gitlab.com/QEF/q-e.git
208 lines
6.3 KiB
Fortran
208 lines
6.3 KiB
Fortran
!
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! Copyright (C) 2001-2007 Quantum ESPRESSO group
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! This file is distributed under the terms of the
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! GNU General Public License. See the file `License'
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! in the root directory of the present distribution,
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! or http://www.gnu.org/copyleft/gpl.txt .
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!
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!
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!----------------------------------------------------------------------
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subroutine dvqpsi_us (ik, uact, addnlcc)
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!----------------------------------------------------------------------
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!
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! This routine calculates dV_bare/dtau * psi for one perturbation
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! with a given q. The displacements are described by a vector u.
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! The result is stored in dvpsi. The routine is called for each k point
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! and for each pattern u. It computes simultaneously all the bands.
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! It implements Eq. B29 of PRB 64, 235118 (2001). The contribution
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! of the local pseudopotential is calculated here, that of the nonlocal
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! pseudopotential in dvqpsi_us_only.
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!
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!
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USE kinds, only : DP
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USE ions_base, ONLY : nat, ityp
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USE cell_base, ONLY : tpiba
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USE gvect, ONLY : nrxx, eigts1, eigts2, eigts3, ig1,ig2,ig3, g, nl, &
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ngm, nr1,nr2,nr3,nrx1,nrx2,nrx3
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USE gsmooth, ONLY : nrxxs, ngms, doublegrid, nls, &
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nr1s, nr2s, nr3s, nrx1s, nrx2s, nrx3s
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USE lsda_mod, ONLY : lsda, isk
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USE noncollin_module, ONLY : npol
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use uspp_param,ONLY : upf
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USE wvfct, ONLY : nbnd, npw, npwx, igk
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USE wavefunctions_module, ONLY: evc
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USE nlcc_ph, ONLY : nlcc_any, drc
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USE eqv, ONLY : dvpsi, dmuxc, vlocq
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USE qpoint, ONLY : npwq, igkq, xq, eigqts, ikks
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implicit none
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!
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! The dummy variables
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!
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integer :: ik
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! input: the k point
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complex(DP) :: uact (3 * nat)
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! input: the pattern of displacements
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logical :: addnlcc
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!
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! And the local variables
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!
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integer :: na, mu, ikk, ig, nt, ibnd, ir, is, ip
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! counter on atoms
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! counter on modes
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! the point k
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! counter on G vectors
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! the type of atom
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! counter on bands
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! counter on real mesh
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complex(DP) :: gtau, gu, fact, u1, u2, u3, gu0
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complex(DP) , allocatable, target :: aux (:)
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complex(DP) , allocatable :: aux1 (:), aux2 (:)
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complex(DP) , pointer :: auxs (:)
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! work space
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call start_clock ('dvqpsi_us')
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if (nlcc_any.and.addnlcc) then
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allocate (aux( nrxx))
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if (doublegrid) then
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allocate (auxs( nrxxs))
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else
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auxs => aux
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endif
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endif
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allocate (aux1( nrxxs))
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allocate (aux2( nrxxs))
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!
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! We start by computing the contribution of the local potential.
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! The computation of the derivative of the local potential is done in
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! reciprocal space while the product with the wavefunction is done in
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! real space
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!
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ikk = ikks(ik)
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dvpsi(:,:) = (0.d0, 0.d0)
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aux1(:) = (0.d0, 0.d0)
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do na = 1, nat
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fact = tpiba * (0.d0, -1.d0) * eigqts (na)
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mu = 3 * (na - 1)
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if (abs (uact (mu + 1) ) + abs (uact (mu + 2) ) + abs (uact (mu + &
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3) ) .gt.1.0d-12) then
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nt = ityp (na)
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u1 = uact (mu + 1)
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u2 = uact (mu + 2)
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u3 = uact (mu + 3)
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gu0 = xq (1) * u1 + xq (2) * u2 + xq (3) * u3
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do ig = 1, ngms
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gtau = eigts1 (ig1 (ig), na) * eigts2 (ig2 (ig), na) * eigts3 ( &
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ig3 (ig), na)
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gu = gu0 + g (1, ig) * u1 + g (2, ig) * u2 + g (3, ig) * u3
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aux1 (nls (ig) ) = aux1 (nls (ig) ) + vlocq (ig, nt) * gu * &
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fact * gtau
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enddo
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endif
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enddo
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!
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! add NLCC when present
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!
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if (nlcc_any.and.addnlcc) then
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aux(:) = (0.d0, 0.d0)
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do na = 1,nat
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fact = tpiba*(0.d0,-1.d0)*eigqts(na)
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mu = 3*(na-1)
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if (abs(uact(mu+1))+abs(uact(mu+2)) &
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+abs(uact(mu+3)).gt.1.0d-12) then
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nt=ityp(na)
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u1 = uact(mu+1)
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u2 = uact(mu+2)
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u3 = uact(mu+3)
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gu0 = xq(1)*u1 +xq(2)*u2+xq(3)*u3
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if (upf(nt)%nlcc) then
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do ig = 1,ngm
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gtau = eigts1(ig1(ig),na)* &
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eigts2(ig2(ig),na)* &
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eigts3(ig3(ig),na)
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gu = gu0+g(1,ig)*u1+g(2,ig)*u2+g(3,ig)*u3
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aux(nl(ig))=aux(nl(ig))+drc(ig,nt)*gu*fact*gtau
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enddo
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endif
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endif
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enddo
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call cft3(aux,nr1,nr2,nr3,nrx1,nrx2,nrx3,+1)
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if (.not.lsda) then
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do ir=1,nrxx
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aux(ir) = aux(ir) * dmuxc(ir,1,1)
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end do
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else
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is=isk(ikk)
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do ir=1,nrxx
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aux(ir) = aux(ir) * 0.5d0 * &
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(dmuxc(ir,is,1)+dmuxc(ir,is,2))
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enddo
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endif
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call cft3(aux,nr1,nr2,nr3,nrx1,nrx2,nrx3,-1)
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if (doublegrid) then
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auxs(:) = (0.d0, 0.d0)
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do ig=1,ngms
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auxs(nls(ig)) = aux(nl(ig))
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enddo
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endif
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aux1(:) = aux1(:) + auxs(:)
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endif
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!
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! Now we compute dV_loc/dtau in real space
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!
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call cft3s (aux1, nr1s, nr2s, nr3s, nrx1s, nrx2s, nrx3s, + 1)
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do ibnd = 1, nbnd
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do ip=1,npol
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aux2(:) = (0.d0, 0.d0)
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if (ip==1) then
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do ig = 1, npw
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aux2 (nls (igk (ig) ) ) = evc (ig, ibnd)
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enddo
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else
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do ig = 1, npw
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aux2 (nls (igk (ig) ) ) = evc (ig+npwx, ibnd)
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enddo
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end if
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!
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! This wavefunction is computed in real space
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!
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call cft3s (aux2, nr1s, nr2s, nr3s, nrx1s, nrx2s, nrx3s, + 2)
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do ir = 1, nrxxs
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aux2 (ir) = aux2 (ir) * aux1 (ir)
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enddo
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!
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! and finally dV_loc/dtau * psi is transformed in reciprocal space
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!
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call cft3s (aux2, nr1s, nr2s, nr3s, nrx1s, nrx2s, nrx3s, - 2)
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if (ip==1) then
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do ig = 1, npwq
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dvpsi (ig, ibnd) = aux2 (nls (igkq (ig) ) )
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enddo
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else
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do ig = 1, npwq
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dvpsi (ig+npwx, ibnd) = aux2 (nls (igkq (ig) ) )
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enddo
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end if
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enddo
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enddo
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!
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deallocate (aux2)
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deallocate (aux1)
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if (nlcc_any.and.addnlcc) then
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deallocate (aux)
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if (doublegrid) deallocate (auxs)
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endif
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!
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! We add the contribution of the nonlocal potential in the US form
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! First a term similar to the KB case.
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! Then a term due to the change of the D coefficients.
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!
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call dvqpsi_us_only (ik, uact)
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call stop_clock ('dvqpsi_us')
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return
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end subroutine dvqpsi_us
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