mirror of https://gitlab.com/QEF/q-e.git
181 lines
5.5 KiB
Fortran
181 lines
5.5 KiB
Fortran
!
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! Copyright (C) 2001 PWSCF group
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! This file is distributed under the terms of the
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! GNU General Public License. See the file `License'
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! in the root directory of the present distribution,
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! or http://www.gnu.org/copyleft/gpl.txt .
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!
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!
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!-----------------------------------------------------------------------
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subroutine do_shift_ew (alat, nat, ntyp, ityp, zv, delta_zv, at, bg, tau, &
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omega, g, gg, ngm, gcutm, gstart, gamma_only, shift_ion)
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!-----------------------------------------------------------------------
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!
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! Calculates Ewald energy with both G- and R-space terms.
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! Determines optimal alpha. Should hopefully work for any structure.
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!
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!
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USE kinds
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implicit none
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!
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! first the dummy variables
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!
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integer :: nat, ntyp, ityp (nat), ngm, gstart
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! input: number of atoms in the unit cell
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! input: number of different types of atoms
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! input: the type of each atom
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! input: number of plane waves for G sum
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! input: first non-zero G vector
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logical :: gamma_only
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real(kind=DP) :: tau (3, nat), g (3, ngm), gg (ngm), zv (ntyp), &
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at (3, 3), bg (3, 3), omega, alat, gcutm, delta_zv(ntyp), &
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shift_ion(nat)
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! input: the positions of the atoms in the cell
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! input: the coordinates of G vectors
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! input: the square moduli of G vectors
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! input: the charge of each type of atoms
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! input: the direct lattice vectors
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! input: the reciprocal lattice vectors
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! input: the volume of the unit cell
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! input: lattice parameter
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! input: cut-off of g vectors
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real(kind=DP) :: ewald
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! output: the ewald energy
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!
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! here the local variables
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!
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integer, parameter :: mxr = 50
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! the maximum number of R vectors included in r
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real(kind=DP), parameter :: tpi = 2.d0 * 3.141592653589793d0
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real(kind=DP), parameter :: e2 = 2.d0
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! the square of the electron charge (Ry atomic units)
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integer :: ng, nr, na, nb, nt, nrm, ipol
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! counter over reciprocal G vectors
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! counter over direct vectors
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! counter on atoms
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! counter on atoms
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! counter on atomic types
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! number of R vectors included in r sum
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! counter on polarization
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real(kind=DP) :: charge, tpiba2, ewaldg, ewaldr, dtau (3), alpha, &
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r (3, mxr), r2 (mxr), rmax, rr, upperbound, fact, arg
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! total ionic charge in the cell
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! length in reciprocal space
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! ewald energy computed in reciprocal space
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! ewald energy computed in real space
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! the difference tau_s - tau_s'
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! alpha term in ewald sum
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! input of the rgen routine ( not used here )
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! the square modulus of R_j-tau_s-tau_s'
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! the maximum radius to consider real space sum
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! buffer variable
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! used to optimize alpha
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complex(kind=DP), allocatable :: rhon(:)
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real(kind=DP), external :: erfc
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allocate (rhon(ngm))
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shift_ion(:) = 0.d0
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tpiba2 = (tpi / alat) **2
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charge = 0.d0
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do na = 1, nat
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charge = charge+zv (ityp (na) )
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enddo
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alpha = 2.9d0
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100 alpha = alpha - 0.1d0
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!
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! choose alpha in order to have convergence in the sum over G
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! upperbound is a safe upper bound for the error in the sum over G
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!
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if (alpha.le.0.d0) call errore ('ewald', 'optimal alpha not found', 1)
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upperbound = 2.d0 * charge**2 * sqrt (2.d0 * alpha / tpi) * erfc ( &
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sqrt (tpiba2 * gcutm / 4.d0 / alpha) )
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if (upperbound.gt.1.0d-7) goto 100
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!
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! G-space sum here.
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! Determine if this processor contains G=0 and set the constant term
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!
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if (gstart==2) then
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do na =1,nat
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shift_ion(na) = - charge * delta_zv(ityp(na)) /alpha/ 4.0
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end do
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endif
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if (gamma_only) then
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fact = 2.d0
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else
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fact = 1.d0
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end if
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do ng = gstart, ngm
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rhon(ng) = (0.d0, 0.d0)
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do na =1, nat
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arg = (g (1, ng) * tau (1, na) + &
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g (2, ng) * tau (2, na) + &
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g (3, ng) * tau (3, na) ) * tpi
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rhon(ng) = rhon(ng) + zv (ityp(na)) * DCMPLX (cos (arg), -sin (arg))
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enddo
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end do
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do na=1,nat
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do ng=gstart, ngm
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arg = (g (1, ng) * tau (1, na) + g (2, ng) * tau (2, na) &
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+ g (3, ng) * tau (3, na) ) * tpi
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shift_ion(na) = shift_ion(na) + fact * delta_zv(ityp(na)) * &
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CONJG(rhon(ng)) * DCMPLX (cos (arg), -sin (arg)) * &
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exp ( -gg(ng)*tpiba2/alpha/4.d0) / gg(ng)/tpiba2
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enddo
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enddo
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shift_ion(:) = 2.d0 * tpi / omega * shift_ion(:)
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!
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! Here add the other constant term
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!
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if (gstart.eq.2) then
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do na = 1, nat
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shift_ion(na) = shift_ion(na) - &
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zv (ityp (na) ) * delta_zv(ityp(na)) * &
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sqrt (8.d0/tpi*alpha)
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enddo
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endif
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!
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! R-space sum here (only for the processor that contains G=0)
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!
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if (gstart.eq.2) then
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rmax = 4.d0 / sqrt (alpha) / alat
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!
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! with this choice terms up to ZiZj*erfc(4) are counted (erfc(4)=2x10^-8
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!
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do na = 1, nat
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do nb = 1, nat
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do ipol = 1, 3
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dtau (ipol) = tau (ipol, na) - tau (ipol, nb)
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enddo
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!
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! generates nearest-neighbors shells
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!
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call rgen (dtau, rmax, mxr, at, bg, r, r2, nrm)
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!
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! and sum to the real space part
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!
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do nr = 1, nrm
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rr = sqrt (r2 (nr) ) * alat
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shift_ion(na) = shift_ion(na) + &
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delta_zv(ityp(na)) * zv (ityp (nb) ) * &
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erfc ( sqrt (alpha) * rr) / rr
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enddo
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enddo
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enddo
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endif
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shift_ion(:) = e2 * shift_ion(:)
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#ifdef __PARA
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call reduce (nat, shift_ion)
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#endif
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deallocate (rhon)
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return
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end subroutine do_shift_ew
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