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adjust.f90
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adjust.f90
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! adjust.f90
! Utility program to allow user to change the density or kinetic energy of MC or MD configuration
PROGRAM adjust
!------------------------------------------------------------------------------------------------!
! This software was written in 2016/17 !
! by Michael P. Allen <[email protected]>/<[email protected]> !
! and Dominic J. Tildesley <[email protected]> ("the authors"), !
! to accompany the book "Computer Simulation of Liquids", second edition, 2017 ("the text"), !
! published by Oxford University Press ("the publishers"). !
! !
! LICENCE !
! Creative Commons CC0 Public Domain Dedication. !
! To the extent possible under law, the authors have dedicated all copyright and related !
! and neighboring rights to this software to the PUBLIC domain worldwide. !
! This software is distributed without any warranty. !
! You should have received a copy of the CC0 Public Domain Dedication along with this software. !
! If not, see <http://creativecommons.org/publicdomain/zero/1.0/>. !
! !
! DISCLAIMER !
! The authors and publishers make no warranties about the software, and disclaim liability !
! for all uses of the software, to the fullest extent permitted by applicable law. !
! The authors and publishers do not recommend use of this software for any purpose. !
! It is made freely available, solely to clarify points made in the text. When using or citing !
! the software, you should not imply endorsement by the authors or publishers. !
!------------------------------------------------------------------------------------------------!
! Takes in a configuration of atoms or molecules
! positions, possibly orientations, and optionally, velocities and angular velocities
! Cubic periodic boundary conditions
! Adjusts the density by an amount delta_rho
! and kinetic energy per particle by an amount delta_kin
! Input configuration and output configuration are assumed to be in simulation units defined by the model
! For example, for Lennard-Jones, sigma = 1
! There is nothing here specific to Lennard-Jones
! We assume unit mass and adjust only the translational kinetic energy
USE, INTRINSIC :: iso_fortran_env, ONLY : input_unit, output_unit, error_unit, iostat_end, iostat_eor
USE config_io_module, ONLY : read_cnf_atoms, read_cnf_mols, write_cnf_atoms, write_cnf_mols
USE maths_module, ONLY : lowercase
IMPLICIT NONE
! Most important variables
REAL :: box ! Box length
REAL :: rho ! Current density
REAL :: kin ! Current kinetic energy per particle
REAL :: delta_rho ! Desired density change
REAL :: delta_kin ! Desired kinetic energy change
REAL :: scale ! Scaling factor
LOGICAL :: velocities
INTEGER :: n, ioerr
REAL, DIMENSION(:,:), ALLOCATABLE :: r ! Positions (3,n)
REAL, DIMENSION(:,:), ALLOCATABLE :: v ! Velocities (3,n)
REAL, DIMENSION(:,:), ALLOCATABLE :: e ! Orientations (3,n) or (0:3,n)
REAL, DIMENSION(:,:), ALLOCATABLE :: w ! Angular velocities (3,n)
CHARACTER(len=7), PARAMETER :: filename = 'cnf.inp'
CHARACTER(len=10) :: molecules ! Character string, input, used to specify molecule_option
INTEGER :: molecule_option ! User option for atom, linear, nonlinear or chain molecule
INTEGER, PARAMETER :: atom = 0, linear = 1, nonlinear = 2, chain = 3
REAL, PARAMETER :: tol = 1.e-9
NAMELIST /nml/ delta_rho, delta_kin, velocities, molecules
! Set default parameters
velocities = .FALSE. ! By default, assume MC configuration
molecules = 'atom' ! Options are 'atom', 'chain', 'linear', 'nonlinear'
delta_rho = 0.0 ! If neither of these two items is changed ...
delta_kin = 0.0 ! ... program will just write out information
! Read parameters from namelist
! Comment out, or replace, this section if you don't like namelists
READ ( unit=input_unit, nml=nml, iostat=ioerr )
IF ( ioerr /= 0 ) THEN
WRITE ( unit=error_unit, fmt='(a,i15)') 'Error reading namelist nml from standard input', ioerr
IF ( ioerr == iostat_eor ) WRITE ( unit=error_unit, fmt='(a)') 'End of record'
IF ( ioerr == iostat_end ) WRITE ( unit=error_unit, fmt='(a)') 'End of file'
STOP 'Error in adjust'
END IF
! Use molecules string to deduce molecule_option
molecules = lowercase(molecules)
IF ( INDEX ( molecules, 'chain' ) /= 0 ) THEN
molecule_option = chain
WRITE ( unit=output_unit, fmt='(a)' ) 'Chain of atoms, no periodic boundaries, no density'
ELSE IF ( INDEX ( molecules, 'nonlinear' ) /= 0 ) THEN
molecule_option = nonlinear
WRITE ( unit=output_unit, fmt='(a)' ) 'Nonlinear molecules, periodic boundaries'
ELSE IF ( INDEX ( molecules, 'linear') /= 0 ) THEN
molecule_option = linear
WRITE ( unit=output_unit, fmt='(a)' ) 'Linear molecules, periodic boundaries'
ELSE IF ( INDEX ( molecules, 'atom') /= 0 ) THEN
molecule_option = atom
WRITE ( unit=output_unit, fmt='(a)' ) 'Atoms, periodic boundaries'
ELSE
WRITE ( unit=error_unit, fmt='(a,a)') 'Unrecognized molecules option: ', molecules
STOP 'Error in adjust'
END IF
IF ( (.NOT. velocities) .AND. ABS(delta_kin) > tol ) STOP 'No kinetic energy change possible'
IF ( molecule_option == chain .AND. ABS(delta_rho) > tol ) STOP 'No density change possible'
! The read_cnf_atoms routine should work in all cases, just to get n and box (or bond)
CALL read_cnf_atoms ( filename, n, box )
WRITE ( unit=output_unit, fmt='(a,t40,i15)' ) 'Number of particles', n
IF ( molecule_option == chain ) THEN
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'Molecular bond length', box ! box plays role of bond
ELSE
rho = REAL(n) / box**3
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'Simulation box length', box
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'Density', rho
END IF
SELECT CASE ( molecule_option )
CASE ( nonlinear)
ALLOCATE ( r(3,n), v(3,n), w(3,n), e(0:3,n) )
CASE default
ALLOCATE ( r(3,n), v(3,n), w(3,n), e(3,n) )
END SELECT
SELECT CASE ( molecule_option )
CASE ( atom, chain )
IF ( velocities ) THEN
CALL read_cnf_atoms ( filename, n, box, r, v )
ELSE
CALL read_cnf_atoms ( filename, n, box, r )
END IF
CASE ( linear, nonlinear )
IF ( velocities ) THEN
CALL read_cnf_mols ( filename, n, box, r, e, v, w )
ELSE
CALL read_cnf_mols ( filename, n, box, r, e )
END IF
END SELECT
IF ( velocities ) THEN
kin = 0.5*SUM(v**2) / REAL(n)
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'Kinetic energy', kin
END IF
IF ( ABS(delta_rho) < tol .AND. ABS(delta_kin) < tol ) THEN
WRITE ( unit=output_unit, fmt='(a)' ) 'No changes requested'
ELSE
IF ( ABS(delta_rho) > tol ) THEN
IF ( rho+delta_rho < 0.0 ) STOP 'New requested density would be negative'
scale = ( rho / (rho+delta_rho) )**(1.0/3.0)
box = box * scale
r(:,:) = r(:,:) * scale
rho = REAL(n) / box**3
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'New density', rho
END IF
IF ( ABS(delta_kin) > tol ) THEN
IF ( kin+delta_kin < 0.0 ) STOP 'New requested kinetic energy would be negative'
scale = SQRT ( (kin+delta_kin) / kin )
v(:,:) = v(:,:) * scale
kin = 0.5*SUM(v**2) / REAL(n)
WRITE ( unit=output_unit, fmt='(a,t40,f15.6)' ) 'New kinetic energy', kin
END IF
SELECT CASE ( molecule_option )
CASE ( atom, chain )
IF ( velocities ) THEN
CALL write_cnf_atoms ( filename, n, box, r, v )
ELSE
CALL write_cnf_atoms ( filename, n, box, r )
END IF
CASE ( linear, nonlinear )
IF ( velocities ) THEN
CALL write_cnf_mols ( filename, n, box, r, e, v, w )
ELSE
CALL write_cnf_mols ( filename, n, box, r, e )
END IF
END SELECT
END IF
DEALLOCATE ( r, v, e, w )
END PROGRAM adjust