! ! Copyright (C) 2001-2007 Quantum ESPRESSO group ! 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 . ! ! !----------------------------------------------------------------------- SUBROUTINE atomic_wfc_nc_proj (ik, wfcatom) !----------------------------------------------------------------------- ! ! This routine computes the superposition of atomic wavefunctions ! for k-point "ik" - output in "wfcatom" - noncolinear case only ! If lspinorb=.TRUE. it makes linear combinations of eigenstates of ! the atomic total angular momenta j and j_z; otherwise, of eigenstates of ! the orbital angular momenta l, l_z and of s_z (the z-component of the spin). ! USE kinds, ONLY : DP USE constants, ONLY : tpi, fpi, pi USE cell_base, ONLY : omega, tpiba USE ions_base, ONLY : nat, ntyp => nsp, ityp, tau USE basis, ONLY : natomwfc USE gvect, ONLY : ig1, ig2, ig3, eigts1, eigts2, eigts3, g USE klist, ONLY : xk USE wvfct, ONLY : npwx, npw, nbnd, igk USE us, ONLY : tab_at, dq USE uspp_param, ONLY : upf USE noncollin_module, ONLY : noncolin, npol, angle1, angle2 USE spin_orb, ONLY : lspinorb, rot_ylm, fcoef, lmaxx ! implicit none ! integer, intent(in) :: ik complex(DP), intent(out) :: wfcatom (npwx, npol, natomwfc) ! integer :: n_starting_wfc, lmax_wfc, nt, l, nb, na, m, lm, ig, iig, & i0, i1, i2, i3, nwfcm real(DP), allocatable :: qg(:), ylm (:,:), chiq (:,:,:), gk (:,:) complex(DP), allocatable :: sk (:), aux(:) complex(DP) :: kphase, lphase real(DP) :: arg, px, ux, vx, wx call start_clock ('atomic_wfc') ! calculate max angular momentum required in wavefunctions lmax_wfc = 0 do nt = 1, ntyp lmax_wfc = MAX ( lmax_wfc, MAXVAL (upf(nt)%lchi(1:upf(nt)%nwfc) ) ) enddo ! nwfcm = MAXVAL ( upf(1:ntyp)%nwfc ) ! allocate ( ylm (npw,(lmax_wfc+1)**2), chiq(npw,nwfcm,ntyp), & sk(npw), gk(3,npw), qg(npw) ) ! do ig = 1, npw gk (1,ig) = xk(1, ik) + g(1, igk(ig) ) gk (2,ig) = xk(2, ik) + g(2, igk(ig) ) gk (3,ig) = xk(3, ik) + g(3, igk(ig) ) qg(ig) = gk(1, ig)**2 + gk(2, ig)**2 + gk(3, ig)**2 enddo ! ! ylm = spherical harmonics ! call ylmr2 ((lmax_wfc+1)**2, npw, gk, qg, ylm) ! ! set now q=|k+G| in atomic units ! do ig = 1, npw qg(ig) = sqrt(qg(ig))*tpiba enddo ! n_starting_wfc = 0 ! ! chiq = radial fourier transform of atomic orbitals chi ! do nt = 1, ntyp do nb = 1, upf(nt)%nwfc if ( upf(nt)%oc (nb) >= 0.d0) then do ig = 1, npw px = qg (ig) / dq - int (qg (ig) / dq) ux = 1.d0 - px vx = 2.d0 - px wx = 3.d0 - px i0 = INT( qg (ig) / dq ) + 1 i1 = i0 + 1 i2 = i0 + 2 i3 = i0 + 3 chiq (ig, nb, nt) = & tab_at (i0, nb, nt) * ux * vx * wx / 6.d0 + & tab_at (i1, nb, nt) * px * vx * wx / 2.d0 - & tab_at (i2, nb, nt) * px * ux * wx / 2.d0 + & tab_at (i3, nb, nt) * px * ux * vx / 6.d0 enddo endif enddo enddo deallocate (qg, gk) allocate ( aux(npw) ) do na = 1, nat arg = (xk(1,ik)*tau(1,na) + xk(2,ik)*tau(2,na) + xk(3,ik)*tau(3,na)) * tpi kphase = CMPLX(cos (arg), - sin (arg) ,kind=DP) ! ! sk is the structure factor ! do ig = 1, npw iig = igk (ig) sk (ig) = kphase * eigts1 (ig1 (iig), na) * eigts2 (ig2 (iig), na) * & eigts3 (ig3 (iig), na) enddo ! nt = ityp (na) do nb = 1, upf(nt)%nwfc if (upf(nt)%oc(nb) >= 0.d0) then l = upf(nt)%lchi(nb) lphase = (0.d0,1.d0)**l ! ! the factor i^l MUST BE PRESENT in order to produce ! wavefunctions for k=0 that are real in real space ! IF ( lspinorb ) THEN ! IF ( upf(nt)%has_so ) THEN ! call atomic_wfc_so ( ) ! ELSE ! call atomic_wfc_so2 ( ) ! ENDIF ! ELSE ! call atomic_wfc_nc_z ( ) ! END IF ! END IF ! END DO ! END DO if (n_starting_wfc /= natomwfc) call errore ('atomic_wfc_nc_proj', & 'internal error: some wfcs were lost ', 1) deallocate(aux, sk, chiq, ylm) call stop_clock ('atomic_wfc') return CONTAINS SUBROUTINE atomic_wfc_so ( ) ! ! ... spin-orbit case ! real(DP) :: fact(2), j real(DP), external :: spinor integer :: ind, ind1, n1, is, sph_ind ! j = upf(nt)%jchi(nb) do m = -l-1, l fact(1) = spinor(l,j,m,1) fact(2) = spinor(l,j,m,2) if (abs(fact(1)) > 1.d-8 .or. abs(fact(2)) > 1.d-8) then n_starting_wfc = n_starting_wfc + 1 if (n_starting_wfc > natomwfc) call errore & ('atomic_wfc_so', 'internal error: too many wfcs', 1) DO is=1,2 IF (abs(fact(is)) > 1.d-8) THEN ind=lmaxx+1+sph_ind(l,j,m,is) aux=(0.d0,0.d0) DO n1=1,2*l+1 ind1=l**2+n1 if (abs(rot_ylm(ind,n1)) > 1.d-8) & aux(:)=aux(:)+rot_ylm(ind,n1)*ylm(:,ind1) ENDDO DO ig=1,npw wfcatom (ig,is,n_starting_wfc) = lphase*fact(is)*& sk(ig)*aux(ig)*chiq (ig, nb, nt) END DO ELSE wfcatom (:,is,n_starting_wfc) = (0.d0,0.d0) END IF END DO END IF END DO ! END SUBROUTINE atomic_wfc_so ! SUBROUTINE atomic_wfc_so2 ( ) ! ! ... spin-orbit case with no spin-orbit PP ! real(DP) :: fact(2), j real(DP), external :: spinor integer :: ind, ind1, n1, n2, is, sph_ind ! DO n2 = l, l + 1 j = n2 - 0.5_dp IF (j > 0.0_dp) THEN DO m = -l-1, l fact(1) = spinor(l,j,m,1) fact(2) = spinor(l,j,m,2) IF (abs(fact(1)) > 1.d-8 .or. abs(fact(2)) > 1.d-8) THEN n_starting_wfc = n_starting_wfc + 1 IF (n_starting_wfc > natomwfc) CALL errore & ('atomic_wfc_so2', 'internal error: too many wfcs', 1) DO is=1,2 IF (abs(fact(is)) > 1.d-8) THEN ind=lmaxx+1+sph_ind(l,j,m,is) aux=(0.0_dp,0.0_dp) DO n1=1,2*l+1 ind1=l**2+n1 IF (abs(rot_ylm(ind,n1)) > 1.d-8) & aux(:)=aux(:)+rot_ylm(ind,n1)*ylm(:,ind1) ENDDO DO ig=1,npw wfcatom (ig,is,n_starting_wfc) = lphase * & fact(is)*sk(ig)*aux(ig)*chiq(ig,nb,nt) ENDDO ENDIF ENDDO ENDIF ENDDO ENDIF ENDDO ! END SUBROUTINE atomic_wfc_so2 ! SUBROUTINE atomic_wfc_nc_z ( ) ! ! ... noncolinear case, magnetization along z ! DO m = 1, 2 * l + 1 lm = l**2 + m n_starting_wfc = n_starting_wfc + 1 if (n_starting_wfc + 2*l + 1 > natomwfc) call errore & ('atomic_wfc_nc', 'internal error: too many wfcs', 1) DO ig=1,npw aux(ig) = sk(ig)*ylm(ig,lm)*chiq(ig,nb,nt) END DO ! DO ig=1,npw wfcatom(ig,1,n_starting_wfc) = aux(ig) wfcatom(ig,2,n_starting_wfc) = (0.0_dp, 0.0_dp) ! wfcatom(ig,1,n_starting_wfc+2*l+1) = (0.0_dp, 0.0_dp) wfcatom(ig,2,n_starting_wfc+2*l+1) = aux(ig) END DO END DO n_starting_wfc = n_starting_wfc + 2*l+1 ! END SUBROUTINE atomic_wfc_nc_z END SUBROUTINE atomic_wfc_nc_proj