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!! |
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!! Copyright (c) 2005 The University of Notre Dame. All Rights Reserved. |
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!! |
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!! The University of Notre Dame grants you ("Licensee") a |
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!! non-exclusive, royalty free, license to use, modify and |
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!! redistribute this software in source and binary code form, provided |
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!! that the following conditions are met: |
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!! |
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!! 1. Acknowledgement of the program authors must be made in any |
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!! publication of scientific results based in part on use of the |
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!! program. An acceptable form of acknowledgement is citation of |
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!! the article in which the program was described (Matthew |
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!! A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher |
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!! J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented |
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!! Parallel Simulation Engine for Molecular Dynamics," |
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!! J. Comput. Chem. 26, pp. 252-271 (2005)) |
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!! |
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!! 2. Redistributions of source code must retain the above copyright |
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!! notice, this list of conditions and the following disclaimer. |
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!! |
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!! 3. Redistributions in binary form must reproduce the above copyright |
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!! notice, this list of conditions and the following disclaimer in the |
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!! documentation and/or other materials provided with the |
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!! distribution. |
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!! |
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!! This software is provided "AS IS," without a warranty of any |
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!! kind. All express or implied conditions, representations and |
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!! warranties, including any implied warranty of merchantability, |
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!! fitness for a particular purpose or non-infringement, are hereby |
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!! excluded. The University of Notre Dame and its licensors shall not |
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!! be liable for any damages suffered by licensee as a result of |
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!! using, modifying or distributing the software or its |
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!! derivatives. In no event will the University of Notre Dame or its |
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!! licensors be liable for any lost revenue, profit or data, or for |
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!! direct, indirect, special, consequential, incidental or punitive |
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!! damages, however caused and regardless of the theory of liability, |
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!! arising out of the use of or inability to use software, even if the |
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!! University of Notre Dame has been advised of the possibility of |
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!! such damages. |
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!! |
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|
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|
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!! Calculates Long Range forces Lennard-Jones interactions. |
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!! @author Charles F. Vardeman II |
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!! @author Matthew Meineke |
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!! @version $Id: LJ.F90,v 1.3 2004-10-21 20:15:25 gezelter Exp $, $Date: 2004-10-21 20:15:25 $, $Name: not supported by cvs2svn $, $Revision: 1.3 $ |
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!! @version $Id: LJ.F90,v 1.24 2006-04-25 02:09:01 gezelter Exp $, $Date: 2006-04-25 02:09:01 $, $Name: not supported by cvs2svn $, $Revision: 1.24 $ |
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|
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module lj |
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use atype_module |
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use switcheroo |
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use vector_class |
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use simulation |
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use status |
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use fForceOptions |
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#ifdef IS_MPI |
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use mpiSimulation |
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#endif |
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|
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implicit none |
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PRIVATE |
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|
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#define __FORTRAN90 |
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#include "UseTheForce/DarkSide/fInteractionMap.h" |
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|
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integer, parameter :: DP = selected_real_kind(15) |
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|
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type, private :: LjType |
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integer :: ident |
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|
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logical, save :: useGeometricDistanceMixing = .false. |
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logical, save :: haveMixingMap = .false. |
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|
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real(kind=DP), save :: defaultCutoff = 0.0_DP |
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> |
logical, save :: defaultShift = .false. |
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logical, save :: haveDefaultCutoff = .false. |
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|
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type, private :: LJtype |
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integer :: atid |
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real(kind=dp) :: sigma |
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real(kind=dp) :: epsilon |
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end type LjType |
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|
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type(LjType), dimension(:), allocatable :: ParameterMap |
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|
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logical, save :: haveMixingMap = .false. |
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|
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logical :: isSoftCore = .false. |
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end type LJtype |
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|
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type, private :: LJList |
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integer :: Nljtypes = 0 |
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integer :: currentLJtype = 0 |
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type(LJtype), pointer :: LJtypes(:) => null() |
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integer, pointer :: atidToLJtype(:) => null() |
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end type LJList |
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|
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type(LJList), save :: LJMap |
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|
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type :: MixParameters |
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real(kind=DP) :: sigma |
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real(kind=DP) :: epsilon |
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real(kind=dp) :: sigma6 |
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real(kind=dp) :: tp6 |
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real(kind=dp) :: tp12 |
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real(kind=dp) :: delta |
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real(kind=dp) :: sigmai |
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real(kind=dp) :: rCut |
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logical :: rCutWasSet = .false. |
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logical :: shiftedPot |
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logical :: isSoftCore = .false. |
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end type MixParameters |
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|
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|
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type(MixParameters), dimension(:,:), allocatable :: MixingMap |
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|
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real(kind=DP), save :: LJ_rcut |
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logical, save :: have_rcut = .false. |
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logical, save :: LJ_do_shift = .false. |
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logical, save :: useGeometricDistanceMixing = .false. |
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|
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!! Public methods and data |
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|
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public :: setCutoffLJ |
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public :: useGeometricMixing |
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|
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public :: newLJtype |
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public :: setLJDefaultCutoff |
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public :: getSigma |
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public :: getEpsilon |
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public :: do_lj_pair |
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public :: newLJtype |
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|
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public :: destroyLJtypes |
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|
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contains |
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|
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subroutine newLJtype(ident, sigma, epsilon, status) |
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integer,intent(in) :: ident |
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subroutine newLJtype(c_ident, sigma, epsilon, isSoftCore, status) |
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integer,intent(in) :: c_ident |
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real(kind=dp),intent(in) :: sigma |
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real(kind=dp),intent(in) :: epsilon |
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integer, intent(in) :: isSoftCore |
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integer,intent(out) :: status |
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integer :: nAtypes |
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integer :: nLJTypes, ntypes, myATID |
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integer, pointer :: MatchList(:) => null() |
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integer :: current |
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|
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status = 0 |
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|
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!! Be simple-minded and assume that we need a ParameterMap that |
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!! is the same size as the total number of atom types |
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! check to see if this is the first time into this routine... |
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if (.not.associated(LJMap%LJtypes)) then |
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|
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if (.not.allocated(ParameterMap)) then |
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call getMatchingElementList(atypes, "is_LennardJones", .true., & |
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nLJTypes, MatchList) |
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|
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nAtypes = getSize(atypes) |
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|
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if (nAtypes == 0) then |
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status = -1 |
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return |
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end if |
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|
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if (.not. allocated(ParameterMap)) then |
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allocate(ParameterMap(nAtypes)) |
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endif |
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|
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LJMap%nLJtypes = nLJTypes |
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|
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allocate(LJMap%LJtypes(nLJTypes)) |
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|
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ntypes = getSize(atypes) |
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|
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allocate(LJMap%atidToLJtype(ntypes)) |
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end if |
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|
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if (ident .gt. size(ParameterMap)) then |
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status = -1 |
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return |
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endif |
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|
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! set the values for ParameterMap for this atom type: |
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LJMap%currentLJtype = LJMap%currentLJtype + 1 |
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current = LJMap%currentLJtype |
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|
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ParameterMap(ident)%ident = ident |
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ParameterMap(ident)%epsilon = epsilon |
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ParameterMap(ident)%sigma = sigma |
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|
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myATID = getFirstMatchingElement(atypes, "c_ident", c_ident) |
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LJMap%atidToLJtype(myATID) = current |
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LJMap%LJtypes(current)%atid = myATID |
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LJMap%LJtypes(current)%sigma = sigma |
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LJMap%LJtypes(current)%epsilon = epsilon |
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if (isSoftCore .eq. 1) then |
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LJMap%LJtypes(current)%isSoftCore = .true. |
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else |
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LJMap%LJtypes(current)%isSoftCore = .false. |
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endif |
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end subroutine newLJtype |
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|
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subroutine setCutoffLJ(rcut, do_shift, status) |
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logical, intent(in):: do_shift |
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integer :: status, myStatus |
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real(kind=dp) :: rcut |
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|
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#define __FORTRAN90 |
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#include "UseTheForce/fSwitchingFunction.h" |
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subroutine setLJDefaultCutoff(thisRcut, shiftedPot) |
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real(kind=dp), intent(in) :: thisRcut |
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logical, intent(in) :: shiftedPot |
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defaultCutoff = thisRcut |
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defaultShift = shiftedPot |
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haveDefaultCutoff = .true. |
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!we only want to build LJ Mixing map if LJ is being used. |
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if(LJMap%nLJTypes /= 0) then |
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call createMixingMap() |
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end if |
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|
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status = 0 |
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end subroutine setLJDefaultCutoff |
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|
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LJ_rcut = rcut |
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LJ_do_shift = do_shift |
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call set_switch(LJ_SWITCH, rcut, rcut) |
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have_rcut = .true. |
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|
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return |
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end subroutine setCutoffLJ |
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> |
function getSigma(atid) result (s) |
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integer, intent(in) :: atid |
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integer :: ljt1 |
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real(kind=dp) :: s |
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|
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subroutine useGeometricMixing() |
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useGeometricDistanceMixing = .true. |
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haveMixingMap = .false. |
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return |
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end subroutine useGeometricMixing |
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|
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subroutine createMixingMap(status) |
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integer :: nAtypes |
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integer :: status |
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integer :: i |
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integer :: j |
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real ( kind = dp ) :: Sigma_i, Sigma_j |
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real ( kind = dp ) :: Epsilon_i, Epsilon_j |
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real ( kind = dp ) :: rcut6 |
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|
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status = 0 |
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|
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nAtypes = size(ParameterMap) |
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|
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if (nAtypes == 0) then |
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status = -1 |
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if (LJMap%currentLJtype == 0) then |
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call handleError("LJ", "No members in LJMap") |
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return |
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end if |
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|
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if (.not.have_rcut) then |
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status = -1 |
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> |
ljt1 = LJMap%atidToLJtype(atid) |
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s = LJMap%LJtypes(ljt1)%sigma |
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> |
|
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end function getSigma |
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|
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function getEpsilon(atid) result (e) |
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integer, intent(in) :: atid |
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integer :: ljt1 |
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real(kind=dp) :: e |
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|
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if (LJMap%currentLJtype == 0) then |
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call handleError("LJ", "No members in LJMap") |
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return |
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endif |
189 |
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|
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if (.not. allocated(MixingMap)) then |
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allocate(MixingMap(nAtypes, nAtypes)) |
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endif |
193 |
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|
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rcut6 = LJ_rcut**6 |
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|
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! This loops through all atypes, even those that don't support LJ forces. |
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do i = 1, nAtypes |
198 |
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|
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Epsilon_i = ParameterMap(i)%epsilon |
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Sigma_i = ParameterMap(i)%sigma |
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|
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! do self mixing rule |
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MixingMap(i,i)%sigma = Sigma_i |
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MixingMap(i,i)%sigma6 = Sigma_i ** 6 |
205 |
< |
MixingMap(i,i)%tp6 = (MixingMap(i,i)%sigma6)/rcut6 |
206 |
< |
MixingMap(i,i)%tp12 = (MixingMap(i,i)%tp6) ** 2 |
207 |
< |
MixingMap(i,i)%epsilon = Epsilon_i |
208 |
< |
MixingMap(i,i)%delta = -4.0_DP * MixingMap(i,i)%epsilon * & |
209 |
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(MixingMap(i,i)%tp12 - MixingMap(i,i)%tp6) |
210 |
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|
211 |
< |
do j = i + 1, nAtypes |
212 |
< |
|
213 |
< |
Epsilon_j = ParameterMap(j)%epsilon |
214 |
< |
Sigma_j = ParameterMap(j)%sigma |
188 |
> |
end if |
189 |
> |
|
190 |
> |
ljt1 = LJMap%atidToLJtype(atid) |
191 |
> |
e = LJMap%LJtypes(ljt1)%epsilon |
192 |
> |
|
193 |
> |
end function getEpsilon |
194 |
> |
|
195 |
> |
subroutine createMixingMap() |
196 |
> |
integer :: nLJtypes, i, j |
197 |
> |
real ( kind = dp ) :: s1, s2, e1, e2 |
198 |
> |
real ( kind = dp ) :: rcut6, tp6, tp12 |
199 |
> |
logical :: isSoftCore1, isSoftCore2, doShift |
200 |
> |
|
201 |
> |
if (LJMap%currentLJtype == 0) then |
202 |
> |
call handleError("LJ", "No members in LJMap") |
203 |
> |
return |
204 |
> |
end if |
205 |
> |
|
206 |
> |
nLJtypes = LJMap%nLJtypes |
207 |
> |
|
208 |
> |
if (.not. allocated(MixingMap)) then |
209 |
> |
allocate(MixingMap(nLJtypes, nLJtypes)) |
210 |
> |
endif |
211 |
> |
|
212 |
> |
useGeometricDistanceMixing = usesGeometricDistanceMixing() |
213 |
> |
do i = 1, nLJtypes |
214 |
> |
|
215 |
> |
s1 = LJMap%LJtypes(i)%sigma |
216 |
> |
e1 = LJMap%LJtypes(i)%epsilon |
217 |
> |
isSoftCore1 = LJMap%LJtypes(i)%isSoftCore |
218 |
> |
|
219 |
> |
do j = i, nLJtypes |
220 |
|
|
221 |
+ |
s2 = LJMap%LJtypes(j)%sigma |
222 |
+ |
e2 = LJMap%LJtypes(j)%epsilon |
223 |
+ |
isSoftCore2 = LJMap%LJtypes(j)%isSoftCore |
224 |
+ |
|
225 |
+ |
MixingMap(i,j)%isSoftCore = isSoftCore1 .or. isSoftCore2 |
226 |
+ |
|
227 |
|
! only the distance parameter uses different mixing policies |
228 |
|
if (useGeometricDistanceMixing) then |
229 |
< |
! only for OPLS as far as we can tell |
173 |
< |
MixingMap(i,j)%sigma = dsqrt(Sigma_i * Sigma_j) |
229 |
> |
MixingMap(i,j)%sigma = dsqrt(s1 * s2) |
230 |
|
else |
231 |
< |
! everyone else |
176 |
< |
MixingMap(i,j)%sigma = 0.5_dp * (Sigma_i + Sigma_j) |
231 |
> |
MixingMap(i,j)%sigma = 0.5_dp * (s1 + s2) |
232 |
|
endif |
233 |
|
|
234 |
< |
! energy parameter is always geometric mean: |
235 |
< |
MixingMap(i,j)%epsilon = dsqrt(Epsilon_i * Epsilon_j) |
236 |
< |
|
237 |
< |
MixingMap(i,j)%sigma6 = (MixingMap(i,j)%sigma)**6 |
238 |
< |
MixingMap(i,j)%tp6 = MixingMap(i,j)%sigma6/rcut6 |
239 |
< |
MixingMap(i,j)%tp12 = (MixingMap(i,j)%tp6) ** 2 |
240 |
< |
|
241 |
< |
MixingMap(i,j)%delta = -4.0_DP * MixingMap(i,j)%epsilon * & |
242 |
< |
(MixingMap(i,j)%tp12 - MixingMap(i,j)%tp6) |
243 |
< |
|
244 |
< |
MixingMap(j,i)%sigma = MixingMap(i,j)%sigma |
245 |
< |
MixingMap(j,i)%sigma6 = MixingMap(i,j)%sigma6 |
246 |
< |
MixingMap(j,i)%tp6 = MixingMap(i,j)%tp6 |
247 |
< |
MixingMap(j,i)%tp12 = MixingMap(i,j)%tp12 |
248 |
< |
MixingMap(j,i)%epsilon = MixingMap(i,j)%epsilon |
249 |
< |
MixingMap(j,i)%delta = MixingMap(i,j)%delta |
250 |
< |
|
251 |
< |
end do |
252 |
< |
end do |
234 |
> |
MixingMap(i,j)%epsilon = dsqrt(e1 * e2) |
235 |
> |
|
236 |
> |
MixingMap(i,j)%sigmai = 1.0_DP / (MixingMap(i,j)%sigma) |
237 |
> |
|
238 |
> |
if (haveDefaultCutoff) then |
239 |
> |
MixingMap(i,j)%shiftedPot = defaultShift |
240 |
> |
else |
241 |
> |
MixingMap(i,j)%shiftedPot = defaultShift |
242 |
> |
endif |
243 |
> |
|
244 |
> |
if (i.ne.j) then |
245 |
> |
MixingMap(j,i)%sigma = MixingMap(i,j)%sigma |
246 |
> |
MixingMap(j,i)%epsilon = MixingMap(i,j)%epsilon |
247 |
> |
MixingMap(j,i)%sigmai = MixingMap(i,j)%sigmai |
248 |
> |
MixingMap(j,i)%rCut = MixingMap(i,j)%rCut |
249 |
> |
MixingMap(j,i)%rCutWasSet = MixingMap(i,j)%rCutWasSet |
250 |
> |
MixingMap(j,i)%shiftedPot = MixingMap(i,j)%shiftedPot |
251 |
> |
MixingMap(j,i)%isSoftCore = MixingMap(i,j)%isSoftCore |
252 |
> |
endif |
253 |
> |
|
254 |
> |
enddo |
255 |
> |
enddo |
256 |
|
|
257 |
+ |
haveMixingMap = .true. |
258 |
+ |
|
259 |
|
end subroutine createMixingMap |
260 |
< |
|
261 |
< |
subroutine do_lj_pair(atom1, atom2, d, rij, r2, sw, vpair, fpair, & |
260 |
> |
|
261 |
> |
subroutine do_lj_pair(atom1, atom2, d, rij, r2, rcut, sw, vpair, fpair, & |
262 |
|
pot, f, do_pot) |
263 |
< |
|
263 |
> |
|
264 |
|
integer, intent(in) :: atom1, atom2 |
265 |
< |
real( kind = dp ), intent(in) :: rij, r2 |
265 |
> |
integer :: atid1, atid2, ljt1, ljt2 |
266 |
> |
real( kind = dp ), intent(in) :: rij, r2, rcut |
267 |
|
real( kind = dp ) :: pot, sw, vpair |
268 |
|
real( kind = dp ), dimension(3,nLocal) :: f |
269 |
|
real( kind = dp ), intent(in), dimension(3) :: d |
273 |
|
! local Variables |
274 |
|
real( kind = dp ) :: drdx, drdy, drdz |
275 |
|
real( kind = dp ) :: fx, fy, fz |
276 |
+ |
real( kind = dp ) :: myPot, myPotC, myDeriv, myDerivC, ros, rcos |
277 |
|
real( kind = dp ) :: pot_temp, dudr |
278 |
< |
real( kind = dp ) :: sigma6 |
278 |
> |
real( kind = dp ) :: sigmai |
279 |
|
real( kind = dp ) :: epsilon |
280 |
< |
real( kind = dp ) :: r6 |
219 |
< |
real( kind = dp ) :: t6 |
220 |
< |
real( kind = dp ) :: t12 |
221 |
< |
real( kind = dp ) :: delta |
280 |
> |
logical :: isSoftCore, shiftedPot |
281 |
|
integer :: id1, id2, localError |
282 |
|
|
283 |
|
if (.not.haveMixingMap) then |
284 |
< |
localError = 0 |
226 |
< |
call createMixingMap(localError) |
227 |
< |
if ( localError .ne. 0 ) then |
228 |
< |
call handleError("LJ", "MixingMap creation failed!") |
229 |
< |
return |
230 |
< |
end if |
284 |
> |
call createMixingMap() |
285 |
|
endif |
286 |
|
|
287 |
|
! Look up the correct parameters in the mixing matrix |
288 |
|
#ifdef IS_MPI |
289 |
< |
sigma6 = MixingMap(atid_Row(atom1),atid_Col(atom2))%sigma6 |
290 |
< |
epsilon = MixingMap(atid_Row(atom1),atid_Col(atom2))%epsilon |
237 |
< |
delta = MixingMap(atid_Row(atom1),atid_Col(atom2))%delta |
289 |
> |
atid1 = atid_Row(atom1) |
290 |
> |
atid2 = atid_Col(atom2) |
291 |
|
#else |
292 |
< |
sigma6 = MixingMap(atid(atom1),atid(atom2))%sigma6 |
293 |
< |
epsilon = MixingMap(atid(atom1),atid(atom2))%epsilon |
241 |
< |
delta = MixingMap(atid(atom1),atid(atom2))%delta |
292 |
> |
atid1 = atid(atom1) |
293 |
> |
atid2 = atid(atom2) |
294 |
|
#endif |
295 |
|
|
296 |
< |
r6 = r2 * r2 * r2 |
297 |
< |
|
298 |
< |
t6 = sigma6/ r6 |
299 |
< |
t12 = t6 * t6 |
300 |
< |
|
301 |
< |
pot_temp = 4.0E0_DP * epsilon * (t12 - t6) |
302 |
< |
if (LJ_do_shift) then |
303 |
< |
pot_temp = pot_temp + delta |
296 |
> |
ljt1 = LJMap%atidToLJtype(atid1) |
297 |
> |
ljt2 = LJMap%atidToLJtype(atid2) |
298 |
> |
|
299 |
> |
sigmai = MixingMap(ljt1,ljt2)%sigmai |
300 |
> |
epsilon = MixingMap(ljt1,ljt2)%epsilon |
301 |
> |
isSoftCore = MixingMap(ljt1,ljt2)%isSoftCore |
302 |
> |
shiftedPot = MixingMap(ljt1,ljt2)%shiftedPot |
303 |
> |
|
304 |
> |
ros = rij * sigmai |
305 |
> |
myPotC = 0.0_DP |
306 |
> |
|
307 |
> |
if (isSoftCore) then |
308 |
> |
|
309 |
> |
call getSoftFunc(ros, myPot, myDeriv) |
310 |
> |
|
311 |
> |
if (shiftedPot) then |
312 |
> |
rcos = rcut * sigmai |
313 |
> |
call getSoftFunc(rcos, myPotC, myDerivC) |
314 |
> |
endif |
315 |
> |
|
316 |
> |
else |
317 |
> |
|
318 |
> |
call getLJfunc(ros, myPot, myDeriv) |
319 |
> |
|
320 |
> |
if (shiftedPot) then |
321 |
> |
rcos = rcut * sigmai |
322 |
> |
call getLJfunc(rcos, myPotC, myDerivC) |
323 |
> |
endif |
324 |
> |
|
325 |
|
endif |
326 |
|
|
327 |
+ |
pot_temp = epsilon * (myPot - myPotC) |
328 |
|
vpair = vpair + pot_temp |
329 |
< |
|
330 |
< |
dudr = sw * 24.0E0_DP * epsilon * (t6 - 2.0E0_DP*t12) / rij |
257 |
< |
|
329 |
> |
dudr = sw * epsilon * myDeriv * sigmai |
330 |
> |
|
331 |
|
drdx = d(1) / rij |
332 |
|
drdy = d(2) / rij |
333 |
|
drdz = d(3) / rij |
334 |
< |
|
334 |
> |
|
335 |
|
fx = dudr * drdx |
336 |
|
fy = dudr * drdy |
337 |
|
fz = dudr * drdz |
338 |
< |
|
266 |
< |
|
338 |
> |
|
339 |
|
#ifdef IS_MPI |
340 |
|
if (do_pot) then |
341 |
< |
pot_Row(atom1) = pot_Row(atom1) + sw*pot_temp*0.5 |
342 |
< |
pot_Col(atom2) = pot_Col(atom2) + sw*pot_temp*0.5 |
341 |
> |
pot_Row(VDW_POT,atom1) = pot_Row(VDW_POT,atom1) + sw*pot_temp*0.5 |
342 |
> |
pot_Col(VDW_POT,atom2) = pot_Col(VDW_POT,atom2) + sw*pot_temp*0.5 |
343 |
|
endif |
344 |
< |
|
344 |
> |
|
345 |
|
f_Row(1,atom1) = f_Row(1,atom1) + fx |
346 |
|
f_Row(2,atom1) = f_Row(2,atom1) + fy |
347 |
|
f_Row(3,atom1) = f_Row(3,atom1) + fz |
348 |
< |
|
348 |
> |
|
349 |
|
f_Col(1,atom2) = f_Col(1,atom2) - fx |
350 |
|
f_Col(2,atom2) = f_Col(2,atom2) - fy |
351 |
|
f_Col(3,atom2) = f_Col(3,atom2) - fz |
352 |
< |
|
352 |
> |
|
353 |
|
#else |
354 |
|
if (do_pot) pot = pot + sw*pot_temp |
355 |
|
|
356 |
|
f(1,atom1) = f(1,atom1) + fx |
357 |
|
f(2,atom1) = f(2,atom1) + fy |
358 |
|
f(3,atom1) = f(3,atom1) + fz |
359 |
< |
|
359 |
> |
|
360 |
|
f(1,atom2) = f(1,atom2) - fx |
361 |
|
f(2,atom2) = f(2,atom2) - fy |
362 |
|
f(3,atom2) = f(3,atom2) - fz |
363 |
|
#endif |
364 |
< |
|
364 |
> |
|
365 |
|
#ifdef IS_MPI |
366 |
|
id1 = AtomRowToGlobal(atom1) |
367 |
|
id2 = AtomColToGlobal(atom2) |
371 |
|
#endif |
372 |
|
|
373 |
|
if (molMembershipList(id1) .ne. molMembershipList(id2)) then |
374 |
< |
|
374 |
> |
|
375 |
|
fpair(1) = fpair(1) + fx |
376 |
|
fpair(2) = fpair(2) + fy |
377 |
|
fpair(3) = fpair(3) + fz |
379 |
|
endif |
380 |
|
|
381 |
|
return |
382 |
< |
|
382 |
> |
|
383 |
|
end subroutine do_lj_pair |
384 |
< |
|
385 |
< |
|
386 |
< |
!! Calculates the mixing for sigma or epslon |
384 |
> |
|
385 |
> |
subroutine destroyLJTypes() |
386 |
> |
|
387 |
> |
LJMap%nLJtypes = 0 |
388 |
> |
LJMap%currentLJtype = 0 |
389 |
|
|
390 |
< |
end module lj |
390 |
> |
if (associated(LJMap%LJtypes)) then |
391 |
> |
deallocate(LJMap%LJtypes) |
392 |
> |
LJMap%LJtypes => null() |
393 |
> |
end if |
394 |
> |
|
395 |
> |
if (associated(LJMap%atidToLJtype)) then |
396 |
> |
deallocate(LJMap%atidToLJtype) |
397 |
> |
LJMap%atidToLJtype => null() |
398 |
> |
end if |
399 |
> |
|
400 |
> |
haveMixingMap = .false. |
401 |
|
|
402 |
< |
subroutine newLJtype(ident, sigma, epsilon, status) |
319 |
< |
use lj, ONLY : module_newLJtype => newLJtype |
320 |
< |
integer, parameter :: DP = selected_real_kind(15) |
321 |
< |
integer,intent(inout) :: ident |
322 |
< |
real(kind=dp),intent(inout) :: sigma |
323 |
< |
real(kind=dp),intent(inout) :: epsilon |
324 |
< |
integer,intent(inout) :: status |
325 |
< |
|
326 |
< |
call module_newLJtype(ident, sigma, epsilon, status) |
327 |
< |
|
328 |
< |
end subroutine newLJtype |
402 |
> |
end subroutine destroyLJTypes |
403 |
|
|
404 |
< |
subroutine useGeometricMixing() |
405 |
< |
use lj, ONLY: module_useGeometricMixing => useGeometricMixing |
406 |
< |
|
407 |
< |
call module_useGeometricMixing() |
408 |
< |
return |
409 |
< |
end subroutine useGeometricMixing |
404 |
> |
subroutine getLJfunc(r, myPot, myDeriv) |
405 |
> |
|
406 |
> |
real(kind=dp), intent(in) :: r |
407 |
> |
real(kind=dp), intent(inout) :: myPot, myDeriv |
408 |
> |
real(kind=dp) :: ri, ri2, ri6, ri7, ri12, ri13 |
409 |
> |
real(kind=dp) :: a, b, c, d, dx |
410 |
> |
integer :: j |
411 |
> |
|
412 |
> |
ri = 1.0_DP / r |
413 |
> |
ri2 = ri*ri |
414 |
> |
ri6 = ri2*ri2*ri2 |
415 |
> |
ri7 = ri6*ri |
416 |
> |
ri12 = ri6*ri6 |
417 |
> |
ri13 = ri12*ri |
418 |
> |
|
419 |
> |
myPot = 4.0_DP * (ri12 - ri6) |
420 |
> |
myDeriv = 24.0_DP * (ri7 - 2.0_DP * ri13) |
421 |
> |
|
422 |
> |
return |
423 |
> |
end subroutine getLJfunc |
424 |
> |
|
425 |
> |
subroutine getSoftFunc(r, myPot, myDeriv) |
426 |
> |
|
427 |
> |
real(kind=dp), intent(in) :: r |
428 |
> |
real(kind=dp), intent(inout) :: myPot, myDeriv |
429 |
> |
real(kind=dp) :: ri, ri2, ri6, ri7 |
430 |
> |
real(kind=dp) :: a, b, c, d, dx |
431 |
> |
integer :: j |
432 |
> |
|
433 |
> |
ri = 1.0_DP / r |
434 |
> |
ri2 = ri*ri |
435 |
> |
ri6 = ri2*ri2*ri2 |
436 |
> |
ri7 = ri6*ri |
437 |
> |
myPot = 4.0_DP * (ri6) |
438 |
> |
myDeriv = - 24.0_DP * ri7 |
439 |
> |
|
440 |
> |
return |
441 |
> |
end subroutine getSoftFunc |
442 |
> |
|
443 |
> |
end module lj |