UseTheForce/DarkSide/electrostatic.F90

!!
!! Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
!!
!! The University of Notre Dame grants you ("Licensee") a
!! non-exclusive, royalty free, license to use, modify and
!! redistribute this software in source and binary code form, provided
!! that the following conditions are met:
!!
!! 1. Acknowledgement of the program authors must be made in any
!!    publication of scientific results based in part on use of the
!!    program.  An acceptable form of acknowledgement is citation of
!!    the article in which the program was described (Matthew
!!    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
!!    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
!!    Parallel Simulation Engine for Molecular Dynamics,"
!!    J. Comput. Chem. 26, pp. 252-271 (2005))
!!
!! 2. Redistributions of source code must retain the above copyright
!!    notice, this list of conditions and the following disclaimer.
!!
!! 3. Redistributions in binary form must reproduce the above copyright
!!    notice, this list of conditions and the following disclaimer in the
!!    documentation and/or other materials provided with the
!!    distribution.
!!
!! This software is provided "AS IS," without a warranty of any
!! kind. All express or implied conditions, representations and
!! warranties, including any implied warranty of merchantability,
!! fitness for a particular purpose or non-infringement, are hereby
!! excluded.  The University of Notre Dame and its licensors shall not
!! be liable for any damages suffered by licensee as a result of
!! using, modifying or distributing the software or its
!! derivatives. In no event will the University of Notre Dame or its
!! licensors be liable for any lost revenue, profit or data, or for
!! direct, indirect, special, consequential, incidental or punitive
!! damages, however caused and regardless of the theory of liability,
!! arising out of the use of or inability to use software, even if the
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!!

module electrostatic_module
  
  use force_globals
  use definitions
  use atype_module
  use vector_class
  use simulation
  use status
#ifdef IS_MPI
  use mpiSimulation
#endif
  implicit none

  PRIVATE

  real(kind=dp), parameter :: pre11 = 332.0637778_dp
  real(kind=dp), parameter :: pre12 = 69.13291783_dp
  real(kind=dp), parameter :: pre22 = 14.39289874_dp
  real(kind=dp), parameter :: pre14 = 0.0_dp

  public :: newElectrostaticType
  public :: setCharge
  public :: setDipoleMoment
  public :: setSplitDipoleDistance
  public :: setQuadrupoleMoments
  public :: doElectrostaticPair
  public :: getCharge
  public :: getDipoleMoment

  type :: Electrostatic
     integer :: c_ident
     logical :: is_Charge = .false.
     logical :: is_Dipole = .false.
     logical :: is_SplitDipole = .false.
     logical :: is_Quadrupole = .false.
     real(kind=DP) :: charge = 0.0_DP
     real(kind=DP) :: dipole_moment = 0.0_DP
     real(kind=DP) :: split_dipole_distance = 0.0_DP
     real(kind=DP), dimension(3) :: quadrupole_moments = 0.0_DP
  end type Electrostatic

  type(Electrostatic), dimension(:), allocatable :: ElectrostaticMap

contains

  subroutine newElectrostaticType(c_ident, is_Charge, is_Dipole, &
       is_SplitDipole, is_Quadrupole, status)
    
    integer, intent(in) :: c_ident
    logical, intent(in) :: is_Charge
    logical, intent(in) :: is_Dipole
    logical, intent(in) :: is_SplitDipole
    logical, intent(in) :: is_Quadrupole
    integer, intent(out) :: status
    integer :: nAtypes, myATID, i, j

    status = 0
    myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
    
    !! Be simple-minded and assume that we need an ElectrostaticMap that
    !! is the same size as the total number of atom types

    if (.not.allocated(ElectrostaticMap)) then
       
       nAtypes = getSize(atypes)
    
       if (nAtypes == 0) then
          status = -1
          return
       end if
       
       if (.not. allocated(ElectrostaticMap)) then
          allocate(ElectrostaticMap(nAtypes))
       endif
       
    end if

    if (myATID .gt. size(ElectrostaticMap)) then
       status = -1
       return
    endif
    
    ! set the values for ElectrostaticMap for this atom type:

    ElectrostaticMap(myATID)%c_ident = c_ident
    ElectrostaticMap(myATID)%is_Charge = is_Charge
    ElectrostaticMap(myATID)%is_Dipole = is_Dipole
    ElectrostaticMap(myATID)%is_SplitDipole = is_SplitDipole
    ElectrostaticMap(myATID)%is_Quadrupole = is_Quadrupole
    
  end subroutine newElectrostaticType

  subroutine setCharge(c_ident, charge, status)
    integer, intent(in) :: c_ident
    real(kind=dp), intent(in) :: charge
    integer, intent(out) :: status
    integer :: myATID

    status = 0
    myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)

    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of setCharge!")
       status = -1
       return
    end if

    if (myATID .gt. size(ElectrostaticMap)) then
       call handleError("electrostatic", "ElectrostaticMap was found to be too small during setCharge!")
       status = -1
       return
    endif

    if (.not.ElectrostaticMap(myATID)%is_Charge) then
       call handleError("electrostatic", "Attempt to setCharge of an atom type that is not a charge!")
       status = -1
       return
    endif       

    ElectrostaticMap(myATID)%charge = charge
  end subroutine setCharge

  subroutine setDipoleMoment(c_ident, dipole_moment, status)
    integer, intent(in) :: c_ident
    real(kind=dp), intent(in) :: dipole_moment
    integer, intent(out) :: status
    integer :: myATID

    status = 0
    myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)

    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of setDipoleMoment!")
       status = -1
       return
    end if

    if (myATID .gt. size(ElectrostaticMap)) then
       call handleError("electrostatic", "ElectrostaticMap was found to be too small during setDipoleMoment!")
       status = -1
       return
    endif

    if (.not.ElectrostaticMap(myATID)%is_Dipole) then
       call handleError("electrostatic", "Attempt to setDipoleMoment of an atom type that is not a dipole!")
       status = -1
       return
    endif

    ElectrostaticMap(myATID)%dipole_moment = dipole_moment
  end subroutine setDipoleMoment

  subroutine setSplitDipoleDistance(c_ident, split_dipole_distance, status)
    integer, intent(in) :: c_ident
    real(kind=dp), intent(in) :: split_dipole_distance
    integer, intent(out) :: status
    integer :: myATID

    status = 0
    myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)

    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of setSplitDipoleDistance!")
       status = -1
       return
    end if

    if (myATID .gt. size(ElectrostaticMap)) then
       call handleError("electrostatic", "ElectrostaticMap was found to be too small during setSplitDipoleDistance!")
       status = -1
       return
    endif

    if (.not.ElectrostaticMap(myATID)%is_SplitDipole) then
       call handleError("electrostatic", "Attempt to setSplitDipoleDistance of an atom type that is not a splitDipole!")
       status = -1
       return
    endif

    ElectrostaticMap(myATID)%split_dipole_distance = split_dipole_distance
  end subroutine setSplitDipoleDistance

  subroutine setQuadrupoleMoments(c_ident, quadrupole_moments, status)
    integer, intent(in) :: c_ident
    real(kind=dp), intent(in), dimension(3) :: quadrupole_moments
    integer, intent(out) :: status
    integer :: myATID, i, j

    status = 0
    myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)

    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of setQuadrupoleMoments!")
       status = -1
       return
    end if

    if (myATID .gt. size(ElectrostaticMap)) then
       call handleError("electrostatic", "ElectrostaticMap was found to be too small during setQuadrupoleMoments!")
       status = -1
       return
    endif

    if (.not.ElectrostaticMap(myATID)%is_Quadrupole) then
       call handleError("electrostatic", "Attempt to setQuadrupoleMoments of an atom type that is not a quadrupole!")
       status = -1
       return
    endif
    
    do i = 1, 3
          ElectrostaticMap(myATID)%quadrupole_moments(i) = &
               quadrupole_moments(i)
       enddo

  end subroutine setQuadrupoleMoments

  
  function getCharge(atid) result (c)
    integer, intent(in) :: atid
    integer :: localError
    real(kind=dp) :: c
    
    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of getCharge!")
       return
    end if
    
    if (.not.ElectrostaticMap(atid)%is_Charge) then
       call handleError("electrostatic", "getCharge was called for an atom type that isn't a charge!")
       return
    endif
    
    c = ElectrostaticMap(atid)%charge
  end function getCharge

  function getDipoleMoment(atid) result (dm)
    integer, intent(in) :: atid
    integer :: localError
    real(kind=dp) :: dm
    
    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of getDipoleMoment!")
       return
    end if
    
    if (.not.ElectrostaticMap(atid)%is_Dipole) then
       call handleError("electrostatic", "getDipoleMoment was called for an atom type that isn't a dipole!")
       return
    endif
    
    dm = ElectrostaticMap(atid)%dipole_moment
  end function getDipoleMoment

  subroutine doElectrostaticPair(atom1, atom2, d, rij, r2, sw, &
       vpair, fpair, pot, eFrame, f, t, do_pot)
    
    logical, intent(in) :: do_pot
    
    integer, intent(in) :: atom1, atom2
    integer :: localError

    real(kind=dp), intent(in) :: rij, r2, sw
    real(kind=dp), intent(in), dimension(3) :: d
    real(kind=dp), intent(inout) :: vpair
    real(kind=dp), intent(inout), dimension(3) :: fpair

    real( kind = dp ) :: pot
    real( kind = dp ), dimension(9,nLocal) :: eFrame
    real( kind = dp ), dimension(3,nLocal) :: f
    real( kind = dp ), dimension(3,nLocal) :: t
    
    real (kind = dp), dimension(3) :: ul_i
    real (kind = dp), dimension(3) :: ul_j

    logical :: i_is_Charge, i_is_Dipole, i_is_SplitDipole, i_is_Quadrupole
    logical :: j_is_Charge, j_is_Dipole, j_is_SplitDipole, j_is_Quadrupole
    integer :: me1, me2, id1, id2
    real (kind=dp) :: q_i, q_j, mu_i, mu_j, d_i, d_j
    real (kind=dp) :: ct_i, ct_j, ct_ij, a1
    real (kind=dp) :: riji, ri, ri2, ri3, ri4
    real (kind=dp) :: pref, vterm, epot, dudr    
    real (kind=dp) :: xhat, yhat, zhat
    real (kind=dp) :: dudx, dudy, dudz
    real (kind=dp) :: drdxj, drdyj, drdzj
    real (kind=dp) :: duduix, duduiy, duduiz, dudujx, dudujy, dudujz
    real (kind=dp) :: scale, sc2, bigR

    if (.not.allocated(ElectrostaticMap)) then
       call handleError("electrostatic", "no ElectrostaticMap was present before first call of do_electrostatic_pair!")
       return
    end if

#ifdef IS_MPI
    me1 = atid_Row(atom1)
    me2 = atid_Col(atom2)
#else
    me1 = atid(atom1)
    me2 = atid(atom2)
#endif

    !! some variables we'll need independent of electrostatic type:

    riji = 1.0d0 / rij

    xhat = d(1) * riji
    yhat = d(2) * riji
    zhat = d(3) * riji

    drdxj = xhat
    drdyj = yhat
    drdzj = zhat

    !! logicals

    i_is_Charge = ElectrostaticMap(me1)%is_Charge
    i_is_Dipole = ElectrostaticMap(me1)%is_Dipole
    i_is_SplitDipole = ElectrostaticMap(me1)%is_SplitDipole
    i_is_Quadrupole = ElectrostaticMap(me1)%is_Quadrupole

    j_is_Charge = ElectrostaticMap(me2)%is_Charge
    j_is_Dipole = ElectrostaticMap(me2)%is_Dipole
    j_is_SplitDipole = ElectrostaticMap(me2)%is_SplitDipole
    j_is_Quadrupole = ElectrostaticMap(me2)%is_Quadrupole

    if (i_is_Charge) then
       q_i = ElectrostaticMap(me1)%charge      
    endif
    
    if (i_is_Dipole) then
       mu_i = ElectrostaticMap(me1)%dipole_moment
#ifdef IS_MPI
       ul_i(1) = eFrame_Row(3,atom1)
       ul_i(2) = eFrame_Row(6,atom1)
       ul_i(3) = eFrame_Row(9,atom1)
#else
       ul_i(1) = eFrame(3,atom1)
       ul_i(2) = eFrame(6,atom1)
       ul_i(3) = eFrame(9,atom1)
#endif
       ct_i = ul_i(1)*drdxj + ul_i(2)*drdyj + ul_i(3)*drdzj

       if (i_is_SplitDipole) then
          d_i = ElectrostaticMap(me1)%split_dipole_distance
       endif
       
    endif

    if (j_is_Charge) then
       q_j = ElectrostaticMap(me2)%charge      
    endif
    
    if (j_is_Dipole) then
       mu_j = ElectrostaticMap(me2)%dipole_moment
#ifdef IS_MPI
       ul_j(1) = eFrame_Col(3,atom2)
       ul_j(2) = eFrame_Col(6,atom2)
       ul_j(3) = eFrame_Col(9,atom2)
#else
       ul_j(1) = eFrame(3,atom2)
       ul_j(2) = eFrame(6,atom2)
       ul_j(3) = eFrame(9,atom2)
#endif
       ct_j = ul_j(1)*drdxj + ul_j(2)*drdyj + ul_j(3)*drdzj

       if (j_is_SplitDipole) then
          d_j = ElectrostaticMap(me2)%split_dipole_distance
       endif
    endif

    epot = 0.0_dp
    dudx = 0.0_dp
    dudy = 0.0_dp
    dudz = 0.0_dp

    duduix = 0.0_dp
    duduiy = 0.0_dp
    duduiz = 0.0_dp

    dudujx = 0.0_dp
    dudujy = 0.0_dp
    dudujz = 0.0_dp

    if (i_is_Charge) then

       if (j_is_Charge) then
          
          vterm = pre11 * q_i * q_j * riji
          vpair = vpair + vterm
          epot = epot + sw*vterm

          dudr  = - sw * vterm * riji

          dudx = dudx + dudr * drdxj
          dudy = dudy + dudr * drdyj
          dudz = dudz + dudr * drdzj
       
       endif

       if (j_is_Dipole) then

          if (j_is_SplitDipole) then
             BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
             ri = 1.0_dp / BigR
             scale = rij * ri
          else
             ri = riji
             scale = 1.0_dp
          endif

          ri2 = ri * ri
          ri3 = ri2 * ri
          sc2 = scale * scale
             
          pref = pre12 * q_i * mu_j
          vterm = pref * ct_j * ri2 * scale
          vpair = vpair + vterm
          epot = epot + sw * vterm

          !! this has a + sign in the () because the rij vector is
          !! r_j - r_i and the charge-dipole potential takes the origin
          !! as the point dipole, which is atom j in this case.

          dudx = dudx + pref * sw * ri3 * ( ul_j(1) + 3.0d0*ct_j*xhat*sc2)
          dudy = dudy + pref * sw * ri3 * ( ul_j(2) + 3.0d0*ct_j*yhat*sc2)
          dudz = dudz + pref * sw * ri3 * ( ul_j(3) + 3.0d0*ct_j*zhat*sc2)

          dudujx = dudujx - pref * sw * ri2 * xhat * scale
          dudujy = dudujy - pref * sw * ri2 * yhat * scale
          dudujz = dudujz - pref * sw * ri2 * zhat * scale
          
       endif

    endif
  
    if (i_is_Dipole) then 
       
       if (j_is_Charge) then

          if (i_is_SplitDipole) then
             BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
             ri = 1.0_dp / BigR
             scale = rij * ri
          else
             ri = riji
             scale = 1.0_dp
          endif

          ri2 = ri * ri
          ri3 = ri2 * ri
          sc2 = scale * scale
             
          pref = pre12 * q_j * mu_i
          vterm = pref * ct_i * ri2 * scale
          vpair = vpair + vterm
          epot = epot + sw * vterm

          dudx = dudx + pref * sw * ri3 * ( ul_i(1) - 3.0d0 * ct_i * xhat*sc2)
          dudy = dudy + pref * sw * ri3 * ( ul_i(2) - 3.0d0 * ct_i * yhat*sc2)
          dudz = dudz + pref * sw * ri3 * ( ul_i(3) - 3.0d0 * ct_i * zhat*sc2)

          duduix = duduix + pref * sw * ri2 * xhat * scale
          duduiy = duduiy + pref * sw * ri2 * yhat * scale
          duduiz = duduiz + pref * sw * ri2 * zhat * scale
       endif

       if (j_is_Dipole) then

          if (i_is_SplitDipole) then
             if (j_is_SplitDipole) then
                BigR = sqrt(r2 + 0.25_dp * d_i * d_i + 0.25_dp * d_j * d_j)
             else
                BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
             endif
             ri = 1.0_dp / BigR
             scale = rij * ri                
          else
             if (j_is_SplitDipole) then
                BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
                ri = 1.0_dp / BigR
                scale = rij * ri                             
             else                
                ri = riji
                scale = 1.0_dp
             endif
          endif

          ct_ij = ul_i(1)*ul_j(1) + ul_i(2)*ul_j(2) + ul_i(3)*ul_j(3)

          ri2 = ri * ri
          ri3 = ri2 * ri
          ri4 = ri2 * ri2
          sc2 = scale * scale

          pref = pre22 * mu_i * mu_j
          vterm = pref * ri3 * (ct_ij - 3.0d0 * ct_i * ct_j * sc2)
          vpair = vpair + vterm
          epot = epot + sw * vterm
          
          a1 = 5.0d0 * ct_i * ct_j * sc2 - ct_ij

          dudx=dudx+pref*sw*3.0d0*ri4*scale*(a1*xhat-ct_i*ul_j(1)-ct_j*ul_i(1))
          dudy=dudy+pref*sw*3.0d0*ri4*scale*(a1*yhat-ct_i*ul_j(2)-ct_j*ul_i(2))
          dudz=dudz+pref*sw*3.0d0*ri4*scale*(a1*zhat-ct_i*ul_j(3)-ct_j*ul_i(3))

          duduix = duduix + pref*sw*ri3*(ul_j(1) - 3.0d0*ct_j*xhat*sc2)
          duduiy = duduiy + pref*sw*ri3*(ul_j(2) - 3.0d0*ct_j*yhat*sc2)
          duduiz = duduiz + pref*sw*ri3*(ul_j(3) - 3.0d0*ct_j*zhat*sc2)

          dudujx = dudujx + pref*sw*ri3*(ul_i(1) - 3.0d0*ct_i*xhat*sc2)
          dudujy = dudujy + pref*sw*ri3*(ul_i(2) - 3.0d0*ct_i*yhat*sc2)
          dudujz = dudujz + pref*sw*ri3*(ul_i(3) - 3.0d0*ct_i*zhat*sc2)
       endif

    endif
    
    if (do_pot) then
#ifdef IS_MPI 
       pot_row(atom1) = pot_row(atom1) + 0.5d0*epot
       pot_col(atom2) = pot_col(atom2) + 0.5d0*epot
#else
       pot = pot + epot
#endif
    endif
        
#ifdef IS_MPI
    f_Row(1,atom1) = f_Row(1,atom1) + dudx
    f_Row(2,atom1) = f_Row(2,atom1) + dudy
    f_Row(3,atom1) = f_Row(3,atom1) + dudz
    
    f_Col(1,atom2) = f_Col(1,atom2) - dudx
    f_Col(2,atom2) = f_Col(2,atom2) - dudy
    f_Col(3,atom2) = f_Col(3,atom2) - dudz
    
    if (i_is_Dipole .or. i_is_Quadrupole) then
       t_Row(1,atom1) = t_Row(1,atom1) - ul_i(2)*duduiz + ul_i(3)*duduiy
       t_Row(2,atom1) = t_Row(2,atom1) - ul_i(3)*duduix + ul_i(1)*duduiz
       t_Row(3,atom1) = t_Row(3,atom1) - ul_i(1)*duduiy + ul_i(2)*duduix
    endif

    if (j_is_Dipole .or. j_is_Quadrupole) then
       t_Col(1,atom2) = t_Col(1,atom2) - ul_j(2)*dudujz + ul_j(3)*dudujy
       t_Col(2,atom2) = t_Col(2,atom2) - ul_j(3)*dudujx + ul_j(1)*dudujz
       t_Col(3,atom2) = t_Col(3,atom2) - ul_j(1)*dudujy + ul_j(2)*dudujx
    endif

#else
    f(1,atom1) = f(1,atom1) + dudx
    f(2,atom1) = f(2,atom1) + dudy
    f(3,atom1) = f(3,atom1) + dudz
    
    f(1,atom2) = f(1,atom2) - dudx
    f(2,atom2) = f(2,atom2) - dudy
    f(3,atom2) = f(3,atom2) - dudz
    
    if (i_is_Dipole .or. i_is_Quadrupole) then
       t(1,atom1) = t(1,atom1) - ul_i(2)*duduiz + ul_i(3)*duduiy
       t(2,atom1) = t(2,atom1) - ul_i(3)*duduix + ul_i(1)*duduiz
       t(3,atom1) = t(3,atom1) - ul_i(1)*duduiy + ul_i(2)*duduix
    endif
       
    if (j_is_Dipole .or. j_is_Quadrupole) then
       t(1,atom2) = t(1,atom2) - ul_j(2)*dudujz + ul_j(3)*dudujy
       t(2,atom2) = t(2,atom2) - ul_j(3)*dudujx + ul_j(1)*dudujz
       t(3,atom2) = t(3,atom2) - ul_j(1)*dudujy + ul_j(2)*dudujx
    endif
#endif
    
#ifdef IS_MPI
    id1 = AtomRowToGlobal(atom1)
    id2 = AtomColToGlobal(atom2)
#else
    id1 = atom1
    id2 = atom2
#endif

    if (molMembershipList(id1) .ne. molMembershipList(id2)) then
       
       fpair(1) = fpair(1) + dudx
       fpair(2) = fpair(2) + dudy
       fpair(3) = fpair(3) + dudz

    endif

    return
  end subroutine doElectrostaticPair
  
end module electrostatic_module
Revision:	421
Committed:	Thu Mar 10 17:54:58 2005 UTC (20 years, 2 months ago) by gezelter
File size:	19979 byte(s)
Log Message:	added fortran-side support for split dipoles
#	User	Rev	Content
1	gezelter	411	!!
2			!! Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3			!!
4			!! The University of Notre Dame grants you ("Licensee") a
5			!! non-exclusive, royalty free, license to use, modify and
6			!! redistribute this software in source and binary code form, provided
7			!! that the following conditions are met:
8			!!
9			!! 1. Acknowledgement of the program authors must be made in any
10			!! publication of scientific results based in part on use of the
11			!! program. An acceptable form of acknowledgement is citation of
12			!! the article in which the program was described (Matthew
13			!! A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14			!! J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15			!! Parallel Simulation Engine for Molecular Dynamics,"
16			!! J. Comput. Chem. 26, pp. 252-271 (2005))
17			!!
18			!! 2. Redistributions of source code must retain the above copyright
19			!! notice, this list of conditions and the following disclaimer.
20			!!
21			!! 3. Redistributions in binary form must reproduce the above copyright
22			!! notice, this list of conditions and the following disclaimer in the
23			!! documentation and/or other materials provided with the
24			!! distribution.
25			!!
26			!! This software is provided "AS IS," without a warranty of any
27			!! kind. All express or implied conditions, representations and
28			!! warranties, including any implied warranty of merchantability,
29			!! fitness for a particular purpose or non-infringement, are hereby
30			!! excluded. The University of Notre Dame and its licensors shall not
31			!! be liable for any damages suffered by licensee as a result of
32			!! using, modifying or distributing the software or its
33			!! derivatives. In no event will the University of Notre Dame or its
34			!! licensors be liable for any lost revenue, profit or data, or for
35			!! direct, indirect, special, consequential, incidental or punitive
36			!! damages, however caused and regardless of the theory of liability,
37			!! arising out of the use of or inability to use software, even if the
38			!! University of Notre Dame has been advised of the possibility of
39			!! such damages.
40			!!
41
42			module electrostatic_module
43
44			use force_globals
45			use definitions
46			use atype_module
47			use vector_class
48			use simulation
49			use status
50			#ifdef IS_MPI
51			use mpiSimulation
52			#endif
53			implicit none
54
55			PRIVATE
56
57			real(kind=dp), parameter :: pre11 = 332.0637778_dp
58			real(kind=dp), parameter :: pre12 = 69.13291783_dp
59			real(kind=dp), parameter :: pre22 = 14.39289874_dp
60	gezelter	421	real(kind=dp), parameter :: pre14 = 0.0_dp
61	gezelter	411
62			public :: newElectrostaticType
63			public :: setCharge
64			public :: setDipoleMoment
65			public :: setSplitDipoleDistance
66			public :: setQuadrupoleMoments
67			public :: doElectrostaticPair
68			public :: getCharge
69			public :: getDipoleMoment
70
71			type :: Electrostatic
72			integer :: c_ident
73			logical :: is_Charge = .false.
74			logical :: is_Dipole = .false.
75			logical :: is_SplitDipole = .false.
76			logical :: is_Quadrupole = .false.
77			real(kind=DP) :: charge = 0.0_DP
78			real(kind=DP) :: dipole_moment = 0.0_DP
79			real(kind=DP) :: split_dipole_distance = 0.0_DP
80			real(kind=DP), dimension(3) :: quadrupole_moments = 0.0_DP
81			end type Electrostatic
82
83			type(Electrostatic), dimension(:), allocatable :: ElectrostaticMap
84
85			contains
86
87			subroutine newElectrostaticType(c_ident, is_Charge, is_Dipole, &
88			is_SplitDipole, is_Quadrupole, status)
89
90			integer, intent(in) :: c_ident
91			logical, intent(in) :: is_Charge
92			logical, intent(in) :: is_Dipole
93			logical, intent(in) :: is_SplitDipole
94			logical, intent(in) :: is_Quadrupole
95			integer, intent(out) :: status
96			integer :: nAtypes, myATID, i, j
97
98			status = 0
99			myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
100
101			!! Be simple-minded and assume that we need an ElectrostaticMap that
102			!! is the same size as the total number of atom types
103
104			if (.not.allocated(ElectrostaticMap)) then
105
106			nAtypes = getSize(atypes)
107
108			if (nAtypes == 0) then
109			status = -1
110			return
111			end if
112
113			if (.not. allocated(ElectrostaticMap)) then
114			allocate(ElectrostaticMap(nAtypes))
115			endif
116
117			end if
118
119			if (myATID .gt. size(ElectrostaticMap)) then
120			status = -1
121			return
122			endif
123
124			! set the values for ElectrostaticMap for this atom type:
125
126			ElectrostaticMap(myATID)%c_ident = c_ident
127			ElectrostaticMap(myATID)%is_Charge = is_Charge
128			ElectrostaticMap(myATID)%is_Dipole = is_Dipole
129			ElectrostaticMap(myATID)%is_SplitDipole = is_SplitDipole
130			ElectrostaticMap(myATID)%is_Quadrupole = is_Quadrupole
131
132			end subroutine newElectrostaticType
133
134			subroutine setCharge(c_ident, charge, status)
135			integer, intent(in) :: c_ident
136			real(kind=dp), intent(in) :: charge
137			integer, intent(out) :: status
138			integer :: myATID
139
140			status = 0
141			myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
142
143			if (.not.allocated(ElectrostaticMap)) then
144			call handleError("electrostatic", "no ElectrostaticMap was present before first call of setCharge!")
145			status = -1
146			return
147			end if
148
149			if (myATID .gt. size(ElectrostaticMap)) then
150			call handleError("electrostatic", "ElectrostaticMap was found to be too small during setCharge!")
151			status = -1
152			return
153			endif
154
155			if (.not.ElectrostaticMap(myATID)%is_Charge) then
156			call handleError("electrostatic", "Attempt to setCharge of an atom type that is not a charge!")
157			status = -1
158			return
159			endif
160
161			ElectrostaticMap(myATID)%charge = charge
162			end subroutine setCharge
163
164			subroutine setDipoleMoment(c_ident, dipole_moment, status)
165			integer, intent(in) :: c_ident
166			real(kind=dp), intent(in) :: dipole_moment
167			integer, intent(out) :: status
168			integer :: myATID
169
170			status = 0
171			myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
172
173			if (.not.allocated(ElectrostaticMap)) then
174			call handleError("electrostatic", "no ElectrostaticMap was present before first call of setDipoleMoment!")
175			status = -1
176			return
177			end if
178
179			if (myATID .gt. size(ElectrostaticMap)) then
180			call handleError("electrostatic", "ElectrostaticMap was found to be too small during setDipoleMoment!")
181			status = -1
182			return
183			endif
184
185			if (.not.ElectrostaticMap(myATID)%is_Dipole) then
186			call handleError("electrostatic", "Attempt to setDipoleMoment of an atom type that is not a dipole!")
187			status = -1
188			return
189			endif
190
191			ElectrostaticMap(myATID)%dipole_moment = dipole_moment
192			end subroutine setDipoleMoment
193
194			subroutine setSplitDipoleDistance(c_ident, split_dipole_distance, status)
195			integer, intent(in) :: c_ident
196			real(kind=dp), intent(in) :: split_dipole_distance
197			integer, intent(out) :: status
198			integer :: myATID
199
200			status = 0
201			myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
202
203			if (.not.allocated(ElectrostaticMap)) then
204			call handleError("electrostatic", "no ElectrostaticMap was present before first call of setSplitDipoleDistance!")
205			status = -1
206			return
207			end if
208
209			if (myATID .gt. size(ElectrostaticMap)) then
210			call handleError("electrostatic", "ElectrostaticMap was found to be too small during setSplitDipoleDistance!")
211			status = -1
212			return
213			endif
214
215			if (.not.ElectrostaticMap(myATID)%is_SplitDipole) then
216			call handleError("electrostatic", "Attempt to setSplitDipoleDistance of an atom type that is not a splitDipole!")
217			status = -1
218			return
219			endif
220
221			ElectrostaticMap(myATID)%split_dipole_distance = split_dipole_distance
222			end subroutine setSplitDipoleDistance
223
224			subroutine setQuadrupoleMoments(c_ident, quadrupole_moments, status)
225			integer, intent(in) :: c_ident
226			real(kind=dp), intent(in), dimension(3) :: quadrupole_moments
227			integer, intent(out) :: status
228			integer :: myATID, i, j
229
230			status = 0
231			myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
232
233			if (.not.allocated(ElectrostaticMap)) then
234			call handleError("electrostatic", "no ElectrostaticMap was present before first call of setQuadrupoleMoments!")
235			status = -1
236			return
237			end if
238
239			if (myATID .gt. size(ElectrostaticMap)) then
240			call handleError("electrostatic", "ElectrostaticMap was found to be too small during setQuadrupoleMoments!")
241			status = -1
242			return
243			endif
244
245			if (.not.ElectrostaticMap(myATID)%is_Quadrupole) then
246			call handleError("electrostatic", "Attempt to setQuadrupoleMoments of an atom type that is not a quadrupole!")
247			status = -1
248			return
249			endif
250
251			do i = 1, 3
252			ElectrostaticMap(myATID)%quadrupole_moments(i) = &
253			quadrupole_moments(i)
254			enddo
255
256			end subroutine setQuadrupoleMoments
257
258
259			function getCharge(atid) result (c)
260			integer, intent(in) :: atid
261			integer :: localError
262			real(kind=dp) :: c
263
264			if (.not.allocated(ElectrostaticMap)) then
265			call handleError("electrostatic", "no ElectrostaticMap was present before first call of getCharge!")
266			return
267			end if
268
269			if (.not.ElectrostaticMap(atid)%is_Charge) then
270			call handleError("electrostatic", "getCharge was called for an atom type that isn't a charge!")
271			return
272			endif
273
274			c = ElectrostaticMap(atid)%charge
275			end function getCharge
276
277			function getDipoleMoment(atid) result (dm)
278			integer, intent(in) :: atid
279			integer :: localError
280			real(kind=dp) :: dm
281
282			if (.not.allocated(ElectrostaticMap)) then
283			call handleError("electrostatic", "no ElectrostaticMap was present before first call of getDipoleMoment!")
284			return
285			end if
286
287			if (.not.ElectrostaticMap(atid)%is_Dipole) then
288			call handleError("electrostatic", "getDipoleMoment was called for an atom type that isn't a dipole!")
289			return
290			endif
291
292			dm = ElectrostaticMap(atid)%dipole_moment
293			end function getDipoleMoment
294
295			subroutine doElectrostaticPair(atom1, atom2, d, rij, r2, sw, &
296			vpair, fpair, pot, eFrame, f, t, do_pot)
297
298			logical, intent(in) :: do_pot
299
300			integer, intent(in) :: atom1, atom2
301			integer :: localError
302
303			real(kind=dp), intent(in) :: rij, r2, sw
304			real(kind=dp), intent(in), dimension(3) :: d
305			real(kind=dp), intent(inout) :: vpair
306			real(kind=dp), intent(inout), dimension(3) :: fpair
307
308			real( kind = dp ) :: pot
309			real( kind = dp ), dimension(9,nLocal) :: eFrame
310			real( kind = dp ), dimension(3,nLocal) :: f
311			real( kind = dp ), dimension(3,nLocal) :: t
312
313			real (kind = dp), dimension(3) :: ul_i
314			real (kind = dp), dimension(3) :: ul_j
315
316			logical :: i_is_Charge, i_is_Dipole, i_is_SplitDipole, i_is_Quadrupole
317			logical :: j_is_Charge, j_is_Dipole, j_is_SplitDipole, j_is_Quadrupole
318			integer :: me1, me2, id1, id2
319			real (kind=dp) :: q_i, q_j, mu_i, mu_j, d_i, d_j
320			real (kind=dp) :: ct_i, ct_j, ct_ij, a1
321	gezelter	421	real (kind=dp) :: riji, ri, ri2, ri3, ri4
322	gezelter	411	real (kind=dp) :: pref, vterm, epot, dudr
323	gezelter	421	real (kind=dp) :: xhat, yhat, zhat
324	gezelter	411	real (kind=dp) :: dudx, dudy, dudz
325			real (kind=dp) :: drdxj, drdyj, drdzj
326			real (kind=dp) :: duduix, duduiy, duduiz, dudujx, dudujy, dudujz
327	gezelter	421	real (kind=dp) :: scale, sc2, bigR
328	gezelter	411
329			if (.not.allocated(ElectrostaticMap)) then
330			call handleError("electrostatic", "no ElectrostaticMap was present before first call of do_electrostatic_pair!")
331			return
332			end if
333
334			#ifdef IS_MPI
335			me1 = atid_Row(atom1)
336			me2 = atid_Col(atom2)
337			#else
338			me1 = atid(atom1)
339			me2 = atid(atom2)
340			#endif
341
342			!! some variables we'll need independent of electrostatic type:
343
344			riji = 1.0d0 / rij
345
346	gezelter	421	xhat = d(1) * riji
347			yhat = d(2) * riji
348			zhat = d(3) * riji
349	gezelter	411
350	gezelter	421	drdxj = xhat
351			drdyj = yhat
352			drdzj = zhat
353	gezelter	411
354			!! logicals
355
356			i_is_Charge = ElectrostaticMap(me1)%is_Charge
357			i_is_Dipole = ElectrostaticMap(me1)%is_Dipole
358			i_is_SplitDipole = ElectrostaticMap(me1)%is_SplitDipole
359			i_is_Quadrupole = ElectrostaticMap(me1)%is_Quadrupole
360
361			j_is_Charge = ElectrostaticMap(me2)%is_Charge
362			j_is_Dipole = ElectrostaticMap(me2)%is_Dipole
363			j_is_SplitDipole = ElectrostaticMap(me2)%is_SplitDipole
364			j_is_Quadrupole = ElectrostaticMap(me2)%is_Quadrupole
365
366			if (i_is_Charge) then
367			q_i = ElectrostaticMap(me1)%charge
368			endif
369
370			if (i_is_Dipole) then
371			mu_i = ElectrostaticMap(me1)%dipole_moment
372			#ifdef IS_MPI
373			ul_i(1) = eFrame_Row(3,atom1)
374			ul_i(2) = eFrame_Row(6,atom1)
375			ul_i(3) = eFrame_Row(9,atom1)
376			#else
377			ul_i(1) = eFrame(3,atom1)
378			ul_i(2) = eFrame(6,atom1)
379			ul_i(3) = eFrame(9,atom1)
380			#endif
381			ct_i = ul_i(1)drdxj + ul_i(2)drdyj + ul_i(3)*drdzj
382
383			if (i_is_SplitDipole) then
384			d_i = ElectrostaticMap(me1)%split_dipole_distance
385			endif
386
387			endif
388
389			if (j_is_Charge) then
390			q_j = ElectrostaticMap(me2)%charge
391			endif
392
393			if (j_is_Dipole) then
394			mu_j = ElectrostaticMap(me2)%dipole_moment
395			#ifdef IS_MPI
396			ul_j(1) = eFrame_Col(3,atom2)
397			ul_j(2) = eFrame_Col(6,atom2)
398			ul_j(3) = eFrame_Col(9,atom2)
399			#else
400			ul_j(1) = eFrame(3,atom2)
401			ul_j(2) = eFrame(6,atom2)
402			ul_j(3) = eFrame(9,atom2)
403			#endif
404			ct_j = ul_j(1)drdxj + ul_j(2)drdyj + ul_j(3)*drdzj
405
406			if (j_is_SplitDipole) then
407			d_j = ElectrostaticMap(me2)%split_dipole_distance
408			endif
409			endif
410
411			epot = 0.0_dp
412			dudx = 0.0_dp
413			dudy = 0.0_dp
414			dudz = 0.0_dp
415
416			duduix = 0.0_dp
417			duduiy = 0.0_dp
418			duduiz = 0.0_dp
419
420			dudujx = 0.0_dp
421			dudujy = 0.0_dp
422			dudujz = 0.0_dp
423
424			if (i_is_Charge) then
425
426			if (j_is_Charge) then
427
428			vterm = pre11 * q_i * q_j * riji
429			vpair = vpair + vterm
430			epot = epot + sw*vterm
431
432			dudr = - sw * vterm * riji
433
434			dudx = dudx + dudr * drdxj
435			dudy = dudy + dudr * drdyj
436			dudz = dudz + dudr * drdzj
437
438			endif
439
440			if (j_is_Dipole) then
441
442	gezelter	421	if (j_is_SplitDipole) then
443			BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
444			ri = 1.0_dp / BigR
445			scale = rij * ri
446			else
447			ri = riji
448			scale = 1.0_dp
449			endif
450	gezelter	411
451	gezelter	421	ri2 = ri * ri
452			ri3 = ri2 * ri
453			sc2 = scale * scale
454
455	gezelter	411	pref = pre12 * q_i * mu_j
456	gezelter	421	vterm = pref * ct_j * ri2 * scale
457	gezelter	411	vpair = vpair + vterm
458			epot = epot + sw * vterm
459
460	gezelter	421	!! this has a + sign in the () because the rij vector is
461			!! r_j - r_i and the charge-dipole potential takes the origin
462			!! as the point dipole, which is atom j in this case.
463	gezelter	411
464	gezelter	421	dudx = dudx + pref * sw * ri3 * ( ul_j(1) + 3.0d0ct_jxhat*sc2)
465			dudy = dudy + pref * sw * ri3 * ( ul_j(2) + 3.0d0ct_jyhat*sc2)
466			dudz = dudz + pref * sw * ri3 * ( ul_j(3) + 3.0d0ct_jzhat*sc2)
467
468			dudujx = dudujx - pref * sw * ri2 * xhat * scale
469			dudujy = dudujy - pref * sw * ri2 * yhat * scale
470			dudujz = dudujz - pref * sw * ri2 * zhat * scale
471	gezelter	411
472			endif
473	gezelter	421
474	gezelter	411	endif
475
476			if (i_is_Dipole) then
477
478			if (j_is_Charge) then
479
480	gezelter	421	if (i_is_SplitDipole) then
481			BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
482			ri = 1.0_dp / BigR
483			scale = rij * ri
484			else
485			ri = riji
486			scale = 1.0_dp
487			endif
488	gezelter	411
489	gezelter	421	ri2 = ri * ri
490			ri3 = ri2 * ri
491			sc2 = scale * scale
492
493	gezelter	411	pref = pre12 * q_j * mu_i
494	gezelter	421	vterm = pref * ct_i * ri2 * scale
495	gezelter	411	vpair = vpair + vterm
496			epot = epot + sw * vterm
497
498	gezelter	421	dudx = dudx + pref * sw * ri3 * ( ul_i(1) - 3.0d0 * ct_i * xhat*sc2)
499			dudy = dudy + pref * sw * ri3 * ( ul_i(2) - 3.0d0 * ct_i * yhat*sc2)
500			dudz = dudz + pref * sw * ri3 * ( ul_i(3) - 3.0d0 * ct_i * zhat*sc2)
501	gezelter	411
502	gezelter	421	duduix = duduix + pref * sw * ri2 * xhat * scale
503			duduiy = duduiy + pref * sw * ri2 * yhat * scale
504			duduiz = duduiz + pref * sw * ri2 * zhat * scale
505	gezelter	411	endif
506
507			if (j_is_Dipole) then
508
509	gezelter	421	if (i_is_SplitDipole) then
510			if (j_is_SplitDipole) then
511			BigR = sqrt(r2 + 0.25_dp * d_i * d_i + 0.25_dp * d_j * d_j)
512			else
513			BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
514			endif
515			ri = 1.0_dp / BigR
516			scale = rij * ri
517			else
518			if (j_is_SplitDipole) then
519			BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
520			ri = 1.0_dp / BigR
521			scale = rij * ri
522			else
523			ri = riji
524			scale = 1.0_dp
525			endif
526			endif
527
528	gezelter	411	ct_ij = ul_i(1)ul_j(1) + ul_i(2)ul_j(2) + ul_i(3)*ul_j(3)
529	gezelter	421
530			ri2 = ri * ri
531			ri3 = ri2 * ri
532	gezelter	411	ri4 = ri2 * ri2
533	gezelter	421	sc2 = scale * scale
534	gezelter	411
535			pref = pre22 * mu_i * mu_j
536	gezelter	421	vterm = pref * ri3 * (ct_ij - 3.0d0 * ct_i * ct_j * sc2)
537	gezelter	411	vpair = vpair + vterm
538			epot = epot + sw * vterm
539
540	gezelter	421	a1 = 5.0d0 * ct_i * ct_j * sc2 - ct_ij
541	gezelter	411
542	gezelter	421	dudx=dudx+prefsw3.0d0ri4scale(a1xhat-ct_iul_j(1)-ct_jul_i(1))
543			dudy=dudy+prefsw3.0d0ri4scale(a1yhat-ct_iul_j(2)-ct_jul_i(2))
544			dudz=dudz+prefsw3.0d0ri4scale(a1zhat-ct_iul_j(3)-ct_jul_i(3))
545	gezelter	411
546	gezelter	421	duduix = duduix + prefswri3(ul_j(1) - 3.0d0ct_jxhatsc2)
547			duduiy = duduiy + prefswri3(ul_j(2) - 3.0d0ct_jyhatsc2)
548			duduiz = duduiz + prefswri3(ul_j(3) - 3.0d0ct_jzhatsc2)
549	gezelter	411
550	gezelter	421	dudujx = dudujx + prefswri3(ul_i(1) - 3.0d0ct_ixhatsc2)
551			dudujy = dudujy + prefswri3(ul_i(2) - 3.0d0ct_iyhatsc2)
552			dudujz = dudujz + prefswri3(ul_i(3) - 3.0d0ct_izhatsc2)
553	gezelter	411	endif
554
555			endif
556
557			if (do_pot) then
558			#ifdef IS_MPI
559			pot_row(atom1) = pot_row(atom1) + 0.5d0*epot
560			pot_col(atom2) = pot_col(atom2) + 0.5d0*epot
561			#else
562			pot = pot + epot
563			#endif
564			endif
565
566			#ifdef IS_MPI
567			f_Row(1,atom1) = f_Row(1,atom1) + dudx
568			f_Row(2,atom1) = f_Row(2,atom1) + dudy
569			f_Row(3,atom1) = f_Row(3,atom1) + dudz
570
571			f_Col(1,atom2) = f_Col(1,atom2) - dudx
572			f_Col(2,atom2) = f_Col(2,atom2) - dudy
573			f_Col(3,atom2) = f_Col(3,atom2) - dudz
574
575			if (i_is_Dipole .or. i_is_Quadrupole) then
576			t_Row(1,atom1) = t_Row(1,atom1) - ul_i(2)duduiz + ul_i(3)duduiy
577			t_Row(2,atom1) = t_Row(2,atom1) - ul_i(3)duduix + ul_i(1)duduiz
578			t_Row(3,atom1) = t_Row(3,atom1) - ul_i(1)duduiy + ul_i(2)duduix
579			endif
580
581			if (j_is_Dipole .or. j_is_Quadrupole) then
582			t_Col(1,atom2) = t_Col(1,atom2) - ul_j(2)dudujz + ul_j(3)dudujy
583			t_Col(2,atom2) = t_Col(2,atom2) - ul_j(3)dudujx + ul_j(1)dudujz
584			t_Col(3,atom2) = t_Col(3,atom2) - ul_j(1)dudujy + ul_j(2)dudujx
585			endif
586
587			#else
588			f(1,atom1) = f(1,atom1) + dudx
589			f(2,atom1) = f(2,atom1) + dudy
590			f(3,atom1) = f(3,atom1) + dudz
591
592			f(1,atom2) = f(1,atom2) - dudx
593			f(2,atom2) = f(2,atom2) - dudy
594			f(3,atom2) = f(3,atom2) - dudz
595
596			if (i_is_Dipole .or. i_is_Quadrupole) then
597			t(1,atom1) = t(1,atom1) - ul_i(2)duduiz + ul_i(3)duduiy
598			t(2,atom1) = t(2,atom1) - ul_i(3)duduix + ul_i(1)duduiz
599			t(3,atom1) = t(3,atom1) - ul_i(1)duduiy + ul_i(2)duduix
600			endif
601
602			if (j_is_Dipole .or. j_is_Quadrupole) then
603			t(1,atom2) = t(1,atom2) - ul_j(2)dudujz + ul_j(3)dudujy
604			t(2,atom2) = t(2,atom2) - ul_j(3)dudujx + ul_j(1)dudujz
605			t(3,atom2) = t(3,atom2) - ul_j(1)dudujy + ul_j(2)dudujx
606			endif
607			#endif
608
609			#ifdef IS_MPI
610			id1 = AtomRowToGlobal(atom1)
611			id2 = AtomColToGlobal(atom2)
612			#else
613			id1 = atom1
614			id2 = atom2
615			#endif
616
617			if (molMembershipList(id1) .ne. molMembershipList(id2)) then
618
619			fpair(1) = fpair(1) + dudx
620			fpair(2) = fpair(2) + dudy
621			fpair(3) = fpair(3) + dudz
622
623			endif
624
625			return
626			end subroutine doElectrostaticPair
627
628			end module electrostatic_module