50 |
|
!! @author Matthew Meineke |
51 |
|
!! @author Christopher Fennell |
52 |
|
!! @author J. Daniel Gezelter |
53 |
< |
!! @version $Id: sticky.F90,v 1.13 2005-05-29 21:16:25 chrisfen Exp $, $Date: 2005-05-29 21:16:25 $, $Name: not supported by cvs2svn $, $Revision: 1.13 $ |
53 |
> |
!! @version $Id: sticky.F90,v 1.20 2006-05-17 15:37:15 gezelter Exp $, $Date: 2006-05-17 15:37:15 $, $Name: not supported by cvs2svn $, $Revision: 1.20 $ |
54 |
|
|
55 |
|
module sticky |
56 |
|
|
60 |
|
use vector_class |
61 |
|
use simulation |
62 |
|
use status |
63 |
+ |
use interpolation |
64 |
|
#ifdef IS_MPI |
65 |
|
use mpiSimulation |
66 |
|
#endif |
67 |
|
implicit none |
68 |
|
|
69 |
|
PRIVATE |
70 |
+ |
#define __FORTRAN90 |
71 |
+ |
#include "UseTheForce/DarkSide/fInteractionMap.h" |
72 |
|
|
73 |
|
public :: newStickyType |
74 |
|
public :: do_sticky_pair |
75 |
|
public :: destroyStickyTypes |
76 |
|
public :: do_sticky_power_pair |
77 |
+ |
public :: getStickyCut |
78 |
+ |
public :: getStickyPowerCut |
79 |
|
|
75 |
– |
|
80 |
|
type :: StickyList |
81 |
|
integer :: c_ident |
82 |
|
real( kind = dp ) :: w0 = 0.0_dp |
87 |
|
real( kind = dp ) :: rlp = 0.0_dp |
88 |
|
real( kind = dp ) :: rup = 0.0_dp |
89 |
|
real( kind = dp ) :: rbig = 0.0_dp |
90 |
+ |
type(cubicSpline) :: stickySpline |
91 |
+ |
type(cubicSpline) :: stickySplineP |
92 |
|
end type StickyList |
93 |
|
|
94 |
|
type(StickyList), dimension(:),allocatable :: StickyMap |
95 |
+ |
logical, save :: hasStickyMap = .false. |
96 |
|
|
97 |
|
contains |
98 |
|
|
103 |
|
real( kind = dp ), intent(in) :: w0, v0, v0p |
104 |
|
real( kind = dp ), intent(in) :: rl, ru |
105 |
|
real( kind = dp ), intent(in) :: rlp, rup |
106 |
+ |
real( kind = dp ), dimension(2) :: rCubVals, sCubVals, rpCubVals, spCubVals |
107 |
|
integer :: nATypes, myATID |
108 |
|
|
109 |
|
|
153 |
|
StickyMap(myATID)%rbig = StickyMap(myATID)%rup |
154 |
|
endif |
155 |
|
|
156 |
+ |
! build the 2 cubic splines for the sticky switching functions |
157 |
+ |
|
158 |
+ |
rCubVals(1) = rl |
159 |
+ |
rCubVals(2) = ru |
160 |
+ |
sCubVals(1) = 1.0_dp |
161 |
+ |
sCubVals(2) = 0.0_dp |
162 |
+ |
call newSpline(StickyMap(myATID)%stickySpline, rCubVals, sCubVals, .true.) |
163 |
+ |
rpCubVals(1) = rlp |
164 |
+ |
rpCubVals(2) = rup |
165 |
+ |
spCubVals(1) = 1.0_dp |
166 |
+ |
spCubVals(2) = 0.0_dp |
167 |
+ |
call newSpline(StickyMap(myATID)%stickySplineP,rpCubVals,spCubVals,.true.) |
168 |
+ |
|
169 |
+ |
hasStickyMap = .true. |
170 |
+ |
|
171 |
|
return |
172 |
|
end subroutine newStickyType |
173 |
|
|
174 |
+ |
function getStickyCut(atomID) result(cutValue) |
175 |
+ |
integer, intent(in) :: atomID |
176 |
+ |
real(kind=dp) :: cutValue |
177 |
+ |
|
178 |
+ |
cutValue = StickyMap(atomID)%rbig |
179 |
+ |
end function getStickyCut |
180 |
+ |
|
181 |
+ |
function getStickyPowerCut(atomID) result(cutValue) |
182 |
+ |
integer, intent(in) :: atomID |
183 |
+ |
real(kind=dp) :: cutValue |
184 |
+ |
|
185 |
+ |
cutValue = StickyMap(atomID)%rbig |
186 |
+ |
end function getStickyPowerCut |
187 |
+ |
|
188 |
|
subroutine do_sticky_pair(atom1, atom2, d, rij, r2, sw, vpair, fpair, & |
189 |
|
pot, A, f, t, do_pot) |
190 |
|
|
225 |
|
real (kind=dp) :: radcomxj, radcomyj, radcomzj |
226 |
|
integer :: id1, id2 |
227 |
|
integer :: me1, me2 |
228 |
< |
real (kind=dp) :: w0, v0, v0p, rl, ru, rlp, rup, rbig |
192 |
< |
|
193 |
< |
if (.not.allocated(StickyMap)) then |
194 |
< |
call handleError("sticky", "no StickyMap was present before first call of do_sticky_pair!") |
195 |
< |
return |
196 |
< |
end if |
228 |
> |
real (kind=dp) :: w0, v0, v0p, rl, ru, rlp, rup, rbig, dx |
229 |
|
|
230 |
|
#ifdef IS_MPI |
231 |
|
me1 = atid_Row(atom1) |
304 |
|
yj2 = yj*yj |
305 |
|
zj2 = zj*zj |
306 |
|
|
275 |
– |
call calc_sw_fnc(rij, rl, ru, rlp, rup, s, sp, dsdr, dspdr) |
307 |
|
|
308 |
< |
wi = 2.0d0*(xi2-yi2)*zi / r3 |
309 |
< |
wj = 2.0d0*(xj2-yj2)*zj / r3 |
308 |
> |
! calculate the switching info. from the splines |
309 |
> |
if (me1.eq.me2) then |
310 |
> |
s = 0.0_dp |
311 |
> |
dsdr = 0.0_dp |
312 |
> |
sp = 0.0_dp |
313 |
> |
dspdr = 0.0_dp |
314 |
> |
|
315 |
> |
if (rij.lt.ru) then |
316 |
> |
if (rij.lt.rl) then |
317 |
> |
s = 1.0_dp |
318 |
> |
dsdr = 0.0_dp |
319 |
> |
else |
320 |
> |
! we are in the switching region |
321 |
> |
dx = rij - rl |
322 |
> |
s = StickyMap(me1)%stickySpline%y(1) + & |
323 |
> |
dx*(dx*(StickyMap(me1)%stickySpline%c(1) + & |
324 |
> |
dx*StickyMap(me1)%stickySpline%d(1))) |
325 |
> |
dsdr = dx*(2.0_dp * StickyMap(me1)%stickySpline%c(1) + & |
326 |
> |
3.0_dp * dx * StickyMap(me1)%stickySpline%d(1)) |
327 |
> |
endif |
328 |
> |
endif |
329 |
> |
if (rij.lt.rup) then |
330 |
> |
if (rij.lt.rlp) then |
331 |
> |
sp = 1.0_dp |
332 |
> |
dspdr = 0.0_dp |
333 |
> |
else |
334 |
> |
! we are in the switching region |
335 |
> |
dx = rij - rlp |
336 |
> |
sp = StickyMap(me1)%stickySplineP%y(1) + & |
337 |
> |
dx*(dx*(StickyMap(me1)%stickySplineP%c(1) + & |
338 |
> |
dx*StickyMap(me1)%stickySplineP%d(1))) |
339 |
> |
dspdr = dx*(2.0_dp * StickyMap(me1)%stickySplineP%c(1) + & |
340 |
> |
3.0_dp * dx * StickyMap(me1)%stickySplineP%d(1)) |
341 |
> |
endif |
342 |
> |
endif |
343 |
> |
else |
344 |
> |
! calculate the switching function explicitly rather than from |
345 |
> |
! the splines with mixed sticky maps |
346 |
> |
call calc_sw_fnc(rij, rl, ru, rlp, rup, s, sp, dsdr, dspdr) |
347 |
> |
endif |
348 |
> |
|
349 |
> |
wi = 2.0_dp*(xi2-yi2)*zi / r3 |
350 |
> |
wj = 2.0_dp*(xj2-yj2)*zj / r3 |
351 |
|
w = wi+wj |
352 |
|
|
353 |
< |
zif = zi/rij - 0.6d0 |
354 |
< |
zis = zi/rij + 0.8d0 |
353 |
> |
zif = zi/rij - 0.6_dp |
354 |
> |
zis = zi/rij + 0.8_dp |
355 |
|
|
356 |
< |
zjf = zj/rij - 0.6d0 |
357 |
< |
zjs = zj/rij + 0.8d0 |
356 |
> |
zjf = zj/rij - 0.6_dp |
357 |
> |
zjs = zj/rij + 0.8_dp |
358 |
|
|
359 |
|
wip = zif*zif*zis*zis - w0 |
360 |
|
wjp = zjf*zjf*zjs*zjs - w0 |
361 |
|
wp = wip + wjp |
362 |
|
|
363 |
< |
vpair = vpair + 0.5d0*(v0*s*w + v0p*sp*wp) |
363 |
> |
vpair = vpair + 0.5_dp*(v0*s*w + v0p*sp*wp) |
364 |
|
if (do_pot) then |
365 |
|
#ifdef IS_MPI |
366 |
< |
pot_row(atom1) = pot_row(atom1) + 0.25d0*(v0*s*w + v0p*sp*wp)*sw |
367 |
< |
pot_col(atom2) = pot_col(atom2) + 0.25d0*(v0*s*w + v0p*sp*wp)*sw |
366 |
> |
pot_row(HB_POT,atom1) = pot_row(HB_POT,atom1) + 0.25_dp*(v0*s*w + v0p*sp*wp)*sw |
367 |
> |
pot_col(HB_POT,atom2) = pot_col(HB_POT,atom2) + 0.25_dp*(v0*s*w + v0p*sp*wp)*sw |
368 |
|
#else |
369 |
< |
pot = pot + 0.5d0*(v0*s*w + v0p*sp*wp)*sw |
369 |
> |
pot = pot + 0.5_dp*(v0*s*w + v0p*sp*wp)*sw |
370 |
|
#endif |
371 |
|
endif |
372 |
|
|
373 |
< |
dwidx = 4.0d0*xi*zi/r3 - 6.0d0*xi*zi*(xi2-yi2)/r5 |
374 |
< |
dwidy = - 4.0d0*yi*zi/r3 - 6.0d0*yi*zi*(xi2-yi2)/r5 |
375 |
< |
dwidz = 2.0d0*(xi2-yi2)/r3 - 6.0d0*zi2*(xi2-yi2)/r5 |
373 |
> |
dwidx = 4.0_dp*xi*zi/r3 - 6.0_dp*xi*zi*(xi2-yi2)/r5 |
374 |
> |
dwidy = - 4.0_dp*yi*zi/r3 - 6.0_dp*yi*zi*(xi2-yi2)/r5 |
375 |
> |
dwidz = 2.0_dp*(xi2-yi2)/r3 - 6.0_dp*zi2*(xi2-yi2)/r5 |
376 |
|
|
377 |
< |
dwjdx = 4.0d0*xj*zj/r3 - 6.0d0*xj*zj*(xj2-yj2)/r5 |
378 |
< |
dwjdy = - 4.0d0*yj*zj/r3 - 6.0d0*yj*zj*(xj2-yj2)/r5 |
379 |
< |
dwjdz = 2.0d0*(xj2-yj2)/r3 - 6.0d0*zj2*(xj2-yj2)/r5 |
377 |
> |
dwjdx = 4.0_dp*xj*zj/r3 - 6.0_dp*xj*zj*(xj2-yj2)/r5 |
378 |
> |
dwjdy = - 4.0_dp*yj*zj/r3 - 6.0_dp*yj*zj*(xj2-yj2)/r5 |
379 |
> |
dwjdz = 2.0_dp*(xj2-yj2)/r3 - 6.0_dp*zj2*(xj2-yj2)/r5 |
380 |
|
|
381 |
|
uglyi = zif*zif*zis + zif*zis*zis |
382 |
|
uglyj = zjf*zjf*zjs + zjf*zjs*zjs |
383 |
|
|
384 |
< |
dwipdx = -2.0d0*xi*zi*uglyi/r3 |
385 |
< |
dwipdy = -2.0d0*yi*zi*uglyi/r3 |
386 |
< |
dwipdz = 2.0d0*(1.0d0/rij - zi2/r3)*uglyi |
384 |
> |
dwipdx = -2.0_dp*xi*zi*uglyi/r3 |
385 |
> |
dwipdy = -2.0_dp*yi*zi*uglyi/r3 |
386 |
> |
dwipdz = 2.0_dp*(1.0_dp/rij - zi2/r3)*uglyi |
387 |
|
|
388 |
< |
dwjpdx = -2.0d0*xj*zj*uglyj/r3 |
389 |
< |
dwjpdy = -2.0d0*yj*zj*uglyj/r3 |
390 |
< |
dwjpdz = 2.0d0*(1.0d0/rij - zj2/r3)*uglyj |
388 |
> |
dwjpdx = -2.0_dp*xj*zj*uglyj/r3 |
389 |
> |
dwjpdy = -2.0_dp*yj*zj*uglyj/r3 |
390 |
> |
dwjpdz = 2.0_dp*(1.0_dp/rij - zj2/r3)*uglyj |
391 |
|
|
392 |
< |
dwidux = 4.0d0*(yi*zi2 + 0.5d0*yi*(xi2-yi2))/r3 |
393 |
< |
dwiduy = 4.0d0*(xi*zi2 - 0.5d0*xi*(xi2-yi2))/r3 |
394 |
< |
dwiduz = - 8.0d0*xi*yi*zi/r3 |
392 |
> |
dwidux = 4.0_dp*(yi*zi2 + 0.5_dp*yi*(xi2-yi2))/r3 |
393 |
> |
dwiduy = 4.0_dp*(xi*zi2 - 0.5_dp*xi*(xi2-yi2))/r3 |
394 |
> |
dwiduz = - 8.0_dp*xi*yi*zi/r3 |
395 |
|
|
396 |
< |
dwjdux = 4.0d0*(yj*zj2 + 0.5d0*yj*(xj2-yj2))/r3 |
397 |
< |
dwjduy = 4.0d0*(xj*zj2 - 0.5d0*xj*(xj2-yj2))/r3 |
398 |
< |
dwjduz = - 8.0d0*xj*yj*zj/r3 |
396 |
> |
dwjdux = 4.0_dp*(yj*zj2 + 0.5_dp*yj*(xj2-yj2))/r3 |
397 |
> |
dwjduy = 4.0_dp*(xj*zj2 - 0.5_dp*xj*(xj2-yj2))/r3 |
398 |
> |
dwjduz = - 8.0_dp*xj*yj*zj/r3 |
399 |
|
|
400 |
< |
dwipdux = 2.0d0*yi*uglyi/rij |
401 |
< |
dwipduy = -2.0d0*xi*uglyi/rij |
402 |
< |
dwipduz = 0.0d0 |
400 |
> |
dwipdux = 2.0_dp*yi*uglyi/rij |
401 |
> |
dwipduy = -2.0_dp*xi*uglyi/rij |
402 |
> |
dwipduz = 0.0_dp |
403 |
|
|
404 |
< |
dwjpdux = 2.0d0*yj*uglyj/rij |
405 |
< |
dwjpduy = -2.0d0*xj*uglyj/rij |
406 |
< |
dwjpduz = 0.0d0 |
404 |
> |
dwjpdux = 2.0_dp*yj*uglyj/rij |
405 |
> |
dwjpduy = -2.0_dp*xj*uglyj/rij |
406 |
> |
dwjpduz = 0.0_dp |
407 |
|
|
408 |
|
! do the torques first since they are easy: |
409 |
|
! remember that these are still in the body fixed axes |
410 |
|
|
411 |
< |
txi = 0.5d0*(v0*s*dwidux + v0p*sp*dwipdux)*sw |
412 |
< |
tyi = 0.5d0*(v0*s*dwiduy + v0p*sp*dwipduy)*sw |
413 |
< |
tzi = 0.5d0*(v0*s*dwiduz + v0p*sp*dwipduz)*sw |
411 |
> |
txi = 0.5_dp*(v0*s*dwidux + v0p*sp*dwipdux)*sw |
412 |
> |
tyi = 0.5_dp*(v0*s*dwiduy + v0p*sp*dwipduy)*sw |
413 |
> |
tzi = 0.5_dp*(v0*s*dwiduz + v0p*sp*dwipduz)*sw |
414 |
|
|
415 |
< |
txj = 0.5d0*(v0*s*dwjdux + v0p*sp*dwjpdux)*sw |
416 |
< |
tyj = 0.5d0*(v0*s*dwjduy + v0p*sp*dwjpduy)*sw |
417 |
< |
tzj = 0.5d0*(v0*s*dwjduz + v0p*sp*dwjpduz)*sw |
415 |
> |
txj = 0.5_dp*(v0*s*dwjdux + v0p*sp*dwjpdux)*sw |
416 |
> |
tyj = 0.5_dp*(v0*s*dwjduy + v0p*sp*dwjpduy)*sw |
417 |
> |
tzj = 0.5_dp*(v0*s*dwjduz + v0p*sp*dwjpduz)*sw |
418 |
|
|
419 |
|
! go back to lab frame using transpose of rotation matrix: |
420 |
|
|
505 |
|
|
506 |
|
! now assemble these with the radial-only terms: |
507 |
|
|
508 |
< |
fxradial = 0.5d0*(v0*dsdr*drdx*w + v0p*dspdr*drdx*wp + fxii + fxji) |
509 |
< |
fyradial = 0.5d0*(v0*dsdr*drdy*w + v0p*dspdr*drdy*wp + fyii + fyji) |
510 |
< |
fzradial = 0.5d0*(v0*dsdr*drdz*w + v0p*dspdr*drdz*wp + fzii + fzji) |
508 |
> |
fxradial = 0.5_dp*(v0*dsdr*drdx*w + v0p*dspdr*drdx*wp + fxii + fxji) |
509 |
> |
fyradial = 0.5_dp*(v0*dsdr*drdy*w + v0p*dspdr*drdy*wp + fyii + fyji) |
510 |
> |
fzradial = 0.5_dp*(v0*dsdr*drdz*w + v0p*dspdr*drdz*wp + fzii + fzji) |
511 |
|
|
512 |
|
#ifdef IS_MPI |
513 |
|
f_Row(1,atom1) = f_Row(1,atom1) + fxradial |
552 |
|
real (kind=dp), intent(inout) :: s, sp, dsdr, dspdr |
553 |
|
|
554 |
|
! distances must be in angstroms |
555 |
< |
|
556 |
< |
if (r.lt.rl) then |
557 |
< |
s = 1.0d0 |
558 |
< |
dsdr = 0.0d0 |
559 |
< |
elseif (r.gt.ru) then |
560 |
< |
s = 0.0d0 |
561 |
< |
dsdr = 0.0d0 |
562 |
< |
else |
563 |
< |
s = ((ru + 2.0d0*r - 3.0d0*rl) * (ru-r)**2) / & |
564 |
< |
((ru - rl)**3) |
565 |
< |
dsdr = 6.0d0*(r-ru)*(r-rl)/((ru - rl)**3) |
555 |
> |
s = 0.0_dp |
556 |
> |
dsdr = 0.0_dp |
557 |
> |
sp = 0.0_dp |
558 |
> |
dspdr = 0.0_dp |
559 |
> |
|
560 |
> |
if (r.lt.ru) then |
561 |
> |
if (r.lt.rl) then |
562 |
> |
s = 1.0_dp |
563 |
> |
dsdr = 0.0_dp |
564 |
> |
else |
565 |
> |
s = ((ru + 2.0_dp*r - 3.0_dp*rl) * (ru-r)**2) / & |
566 |
> |
((ru - rl)**3) |
567 |
> |
dsdr = 6.0_dp*(r-ru)*(r-rl)/((ru - rl)**3) |
568 |
> |
endif |
569 |
|
endif |
570 |
|
|
571 |
< |
if (r.lt.rlp) then |
572 |
< |
sp = 1.0d0 |
573 |
< |
dspdr = 0.0d0 |
574 |
< |
elseif (r.gt.rup) then |
575 |
< |
sp = 0.0d0 |
576 |
< |
dspdr = 0.0d0 |
577 |
< |
else |
578 |
< |
sp = ((rup + 2.0d0*r - 3.0d0*rlp) * (rup-r)**2) / & |
579 |
< |
((rup - rlp)**3) |
505 |
< |
dspdr = 6.0d0*(r-rup)*(r-rlp)/((rup - rlp)**3) |
571 |
> |
if (r.lt.rup) then |
572 |
> |
if (r.lt.rlp) then |
573 |
> |
sp = 1.0_dp |
574 |
> |
dspdr = 0.0_dp |
575 |
> |
else |
576 |
> |
sp = ((rup + 2.0_dp*r - 3.0_dp*rlp) * (rup-r)**2) / & |
577 |
> |
((rup - rlp)**3) |
578 |
> |
dspdr = 6.0_dp*(r-rup)*(r-rlp)/((rup - rlp)**3) |
579 |
> |
endif |
580 |
|
endif |
581 |
|
|
582 |
|
return |
662 |
|
|
663 |
|
if ( rij .LE. rbig ) then |
664 |
|
|
665 |
< |
rI = 1.0d0/rij |
665 |
> |
rI = 1.0_dp/rij |
666 |
|
rI2 = rI*rI |
667 |
|
rI3 = rI2*rI |
668 |
|
rI4 = rI2*rI2 |
724 |
|
|
725 |
|
call calc_sw_fnc(rij, rl, ru, rlp, rup, s, sp, dsdr, dspdr) |
726 |
|
|
727 |
< |
frac1 = 0.25d0 |
728 |
< |
frac2 = 0.75d0 |
727 |
> |
frac1 = 0.25_dp |
728 |
> |
frac2 = 0.75_dp |
729 |
|
|
730 |
< |
wi = 2.0d0*(xi2-yi2)*zi*rI3 |
731 |
< |
wj = 2.0d0*(xj2-yj2)*zj*rI3 |
730 |
> |
wi = 2.0_dp*(xi2-yi2)*zi*rI3 |
731 |
> |
wj = 2.0_dp*(xj2-yj2)*zj*rI3 |
732 |
|
|
733 |
|
wi2 = wi*wi |
734 |
|
wj2 = wj*wj |
735 |
|
|
736 |
|
w = frac1*wi*wi2 + frac2*wi + frac1*wj*wj2 + frac2*wj + v0p |
737 |
|
|
738 |
< |
vpair = vpair + 0.5d0*(v0*s*w) |
738 |
> |
vpair = vpair + 0.5_dp*(v0*s*w) |
739 |
|
|
740 |
|
if (do_pot) then |
741 |
|
#ifdef IS_MPI |
742 |
< |
pot_row(atom1) = pot_row(atom1) + 0.25d0*(v0*s*w)*sw |
743 |
< |
pot_col(atom2) = pot_col(atom2) + 0.25d0*(v0*s*w)*sw |
742 |
> |
pot_row(HB_POT,atom1) = pot_row(HB_POT,atom1) + 0.25_dp*(v0*s*w)*sw |
743 |
> |
pot_col(HB_POT,atom2) = pot_col(HB_POT,atom2) + 0.25_dp*(v0*s*w)*sw |
744 |
|
#else |
745 |
< |
pot = pot + 0.5d0*(v0*s*w)*sw |
745 |
> |
pot = pot + 0.5_dp*(v0*s*w)*sw |
746 |
|
#endif |
747 |
|
endif |
748 |
|
|
749 |
< |
dwidx = ( 4.0d0*xi*zi*rI3 - 6.0d0*xi*zi*(xi2-yi2)*rI5 ) |
750 |
< |
dwidy = ( -4.0d0*yi*zi*rI3 - 6.0d0*yi*zi*(xi2-yi2)*rI5 ) |
751 |
< |
dwidz = ( 2.0d0*(xi2-yi2)*rI3 - 6.0d0*zi2*(xi2-yi2)*rI5 ) |
749 |
> |
dwidx = ( 4.0_dp*xi*zi*rI3 - 6.0_dp*xi*zi*(xi2-yi2)*rI5 ) |
750 |
> |
dwidy = ( -4.0_dp*yi*zi*rI3 - 6.0_dp*yi*zi*(xi2-yi2)*rI5 ) |
751 |
> |
dwidz = ( 2.0_dp*(xi2-yi2)*rI3 - 6.0_dp*zi2*(xi2-yi2)*rI5 ) |
752 |
|
|
753 |
< |
dwidx = frac1*3.0d0*wi2*dwidx + frac2*dwidx |
754 |
< |
dwidy = frac1*3.0d0*wi2*dwidy + frac2*dwidy |
755 |
< |
dwidz = frac1*3.0d0*wi2*dwidz + frac2*dwidz |
753 |
> |
dwidx = frac1*3.0_dp*wi2*dwidx + frac2*dwidx |
754 |
> |
dwidy = frac1*3.0_dp*wi2*dwidy + frac2*dwidy |
755 |
> |
dwidz = frac1*3.0_dp*wi2*dwidz + frac2*dwidz |
756 |
|
|
757 |
< |
dwjdx = ( 4.0d0*xj*zj*rI3 - 6.0d0*xj*zj*(xj2-yj2)*rI5 ) |
758 |
< |
dwjdy = ( -4.0d0*yj*zj*rI3 - 6.0d0*yj*zj*(xj2-yj2)*rI5 ) |
759 |
< |
dwjdz = ( 2.0d0*(xj2-yj2)*rI3 - 6.0d0*zj2*(xj2-yj2)*rI5 ) |
757 |
> |
dwjdx = ( 4.0_dp*xj*zj*rI3 - 6.0_dp*xj*zj*(xj2-yj2)*rI5 ) |
758 |
> |
dwjdy = ( -4.0_dp*yj*zj*rI3 - 6.0_dp*yj*zj*(xj2-yj2)*rI5 ) |
759 |
> |
dwjdz = ( 2.0_dp*(xj2-yj2)*rI3 - 6.0_dp*zj2*(xj2-yj2)*rI5 ) |
760 |
|
|
761 |
< |
dwjdx = frac1*3.0d0*wj2*dwjdx + frac2*dwjdx |
762 |
< |
dwjdy = frac1*3.0d0*wj2*dwjdy + frac2*dwjdy |
763 |
< |
dwjdz = frac1*3.0d0*wj2*dwjdz + frac2*dwjdz |
761 |
> |
dwjdx = frac1*3.0_dp*wj2*dwjdx + frac2*dwjdx |
762 |
> |
dwjdy = frac1*3.0_dp*wj2*dwjdy + frac2*dwjdy |
763 |
> |
dwjdz = frac1*3.0_dp*wj2*dwjdz + frac2*dwjdz |
764 |
|
|
765 |
< |
dwidux = ( 4.0d0*(yi*zi2 + 0.5d0*yi*(xi2-yi2))*rI3 ) |
766 |
< |
dwiduy = ( 4.0d0*(xi*zi2 - 0.5d0*xi*(xi2-yi2))*rI3 ) |
767 |
< |
dwiduz = ( -8.0d0*xi*yi*zi*rI3 ) |
765 |
> |
dwidux = ( 4.0_dp*(yi*zi2 + 0.5_dp*yi*(xi2-yi2))*rI3 ) |
766 |
> |
dwiduy = ( 4.0_dp*(xi*zi2 - 0.5_dp*xi*(xi2-yi2))*rI3 ) |
767 |
> |
dwiduz = ( -8.0_dp*xi*yi*zi*rI3 ) |
768 |
|
|
769 |
< |
dwidux = frac1*3.0d0*wi2*dwidux + frac2*dwidux |
770 |
< |
dwiduy = frac1*3.0d0*wi2*dwiduy + frac2*dwiduy |
771 |
< |
dwiduz = frac1*3.0d0*wi2*dwiduz + frac2*dwiduz |
769 |
> |
dwidux = frac1*3.0_dp*wi2*dwidux + frac2*dwidux |
770 |
> |
dwiduy = frac1*3.0_dp*wi2*dwiduy + frac2*dwiduy |
771 |
> |
dwiduz = frac1*3.0_dp*wi2*dwiduz + frac2*dwiduz |
772 |
|
|
773 |
< |
dwjdux = ( 4.0d0*(yj*zj2 + 0.5d0*yj*(xj2-yj2))*rI3 ) |
774 |
< |
dwjduy = ( 4.0d0*(xj*zj2 - 0.5d0*xj*(xj2-yj2))*rI3 ) |
775 |
< |
dwjduz = ( -8.0d0*xj*yj*zj*rI3 ) |
773 |
> |
dwjdux = ( 4.0_dp*(yj*zj2 + 0.5_dp*yj*(xj2-yj2))*rI3 ) |
774 |
> |
dwjduy = ( 4.0_dp*(xj*zj2 - 0.5_dp*xj*(xj2-yj2))*rI3 ) |
775 |
> |
dwjduz = ( -8.0_dp*xj*yj*zj*rI3 ) |
776 |
|
|
777 |
< |
dwjdux = frac1*3.0d0*wj2*dwjdux + frac2*dwjdux |
778 |
< |
dwjduy = frac1*3.0d0*wj2*dwjduy + frac2*dwjduy |
779 |
< |
dwjduz = frac1*3.0d0*wj2*dwjduz + frac2*dwjduz |
777 |
> |
dwjdux = frac1*3.0_dp*wj2*dwjdux + frac2*dwjdux |
778 |
> |
dwjduy = frac1*3.0_dp*wj2*dwjduy + frac2*dwjduy |
779 |
> |
dwjduz = frac1*3.0_dp*wj2*dwjduz + frac2*dwjduz |
780 |
|
|
781 |
|
! do the torques first since they are easy: |
782 |
|
! remember that these are still in the body fixed axes |
783 |
|
|
784 |
< |
txi = 0.5d0*(v0*s*dwidux)*sw |
785 |
< |
tyi = 0.5d0*(v0*s*dwiduy)*sw |
786 |
< |
tzi = 0.5d0*(v0*s*dwiduz)*sw |
784 |
> |
txi = 0.5_dp*(v0*s*dwidux)*sw |
785 |
> |
tyi = 0.5_dp*(v0*s*dwiduy)*sw |
786 |
> |
tzi = 0.5_dp*(v0*s*dwiduz)*sw |
787 |
|
|
788 |
< |
txj = 0.5d0*(v0*s*dwjdux)*sw |
789 |
< |
tyj = 0.5d0*(v0*s*dwjduy)*sw |
790 |
< |
tzj = 0.5d0*(v0*s*dwjduz)*sw |
788 |
> |
txj = 0.5_dp*(v0*s*dwjdux)*sw |
789 |
> |
tyj = 0.5_dp*(v0*s*dwjduy)*sw |
790 |
> |
tzj = 0.5_dp*(v0*s*dwjduz)*sw |
791 |
|
|
792 |
|
! go back to lab frame using transpose of rotation matrix: |
793 |
|
|
878 |
|
|
879 |
|
! now assemble these with the radial-only terms: |
880 |
|
|
881 |
< |
fxradial = 0.5d0*(v0*dsdr*w*drdx + fxii + fxji) |
882 |
< |
fyradial = 0.5d0*(v0*dsdr*w*drdy + fyii + fyji) |
883 |
< |
fzradial = 0.5d0*(v0*dsdr*w*drdz + fzii + fzji) |
881 |
> |
fxradial = 0.5_dp*(v0*dsdr*w*drdx + fxii + fxji) |
882 |
> |
fyradial = 0.5_dp*(v0*dsdr*w*drdy + fyii + fyji) |
883 |
> |
fzradial = 0.5_dp*(v0*dsdr*w*drdz + fzii + fzji) |
884 |
|
|
885 |
|
#ifdef IS_MPI |
886 |
|
f_Row(1,atom1) = f_Row(1,atom1) + fxradial |