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Comparing trunk/OOPSE-4/src/UseTheForce/DarkSide/electrostatic.F90 (file contents):
Revision 2153 by chrisfen, Fri Apr 8 14:43:06 2005 UTC vs.
Revision 2402 by chrisfen, Tue Nov 1 19:09:30 2005 UTC

#	Line 40 | Line 40 | module electrostatic_module
40		!!
41
42		module electrostatic_module
43	<
43	>
44		use force_globals
45		use definitions
46		use atype_module
#	Line 54 | Line 54 | module electrostatic_module
54
55		PRIVATE
56
57	+
58	+	#define __FORTRAN90
59	+	#include "UseTheForce/DarkSide/fInteractionMap.h"
60	+	#include "UseTheForce/DarkSide/fElectrostaticSummationMethod.h"
61	+
62	+
63		!! these prefactors convert the multipole interactions into kcal / mol
64		!! all were computed assuming distances are measured in angstroms
65		!! Charge-Charge, assuming charges are measured in electrons
#	Line 68 | Line 74 | module electrostatic_module
74		!! This unit is also known affectionately as an esu centi-barn.
75		real(kind=dp), parameter :: pre14 = 69.13373_dp
76
77	+	!! variables to handle different summation methods for long-range electrostatics:
78	+	integer, save :: summationMethod = NONE
79	+	logical, save :: summationMethodChecked = .false.
80	+	real(kind=DP), save :: defaultCutoff = 0.0_DP
81	+	real(kind=DP), save :: defaultCutoff2 = 0.0_DP
82	+	logical, save :: haveDefaultCutoff = .false.
83	+	real(kind=DP), save :: dampingAlpha = 0.0_DP
84	+	logical, save :: haveDampingAlpha = .false.
85	+	real(kind=DP), save :: dielectric = 1.0_DP
86	+	logical, save :: haveDielectric = .false.
87	+	real(kind=DP), save :: constERFC = 0.0_DP
88	+	real(kind=DP), save :: constEXP = 0.0_DP
89	+	real(kind=dp), save :: rcuti = 0.0_DP
90	+	real(kind=dp), save :: rcuti2 = 0.0_DP
91	+	real(kind=dp), save :: rcuti3 = 0.0_DP
92	+	real(kind=dp), save :: rcuti4 = 0.0_DP
93	+	real(kind=dp), save :: alphaPi = 0.0_DP
94	+	real(kind=dp), save :: invRootPi = 0.0_DP
95	+	real(kind=dp), save :: rrf = 1.0_DP
96	+	real(kind=dp), save :: rt = 1.0_DP
97	+	real(kind=dp), save :: rrfsq = 1.0_DP
98	+	real(kind=dp), save :: preRF = 0.0_DP
99	+	real(kind=dp), save :: preRF2 = 0.0_DP
100	+
101	+	#ifdef __IFC
102	+	! error function for ifc version > 7.
103	+	double precision, external :: derfc
104	+	#endif
105	+
106	+	public :: setElectrostaticSummationMethod
107	+	public :: setElectrostaticCutoffRadius
108	+	public :: setDampedWolfAlpha
109	+	public :: setReactionFieldDielectric
110		public :: newElectrostaticType
111		public :: setCharge
112		public :: setDipoleMoment
#	Line 76 | Line 115 | module electrostatic_module
115		public :: doElectrostaticPair
116		public :: getCharge
117		public :: getDipoleMoment
118	<	public :: pre22
118	>	public :: destroyElectrostaticTypes
119	>	public :: self_self
120	>	public :: rf_self_excludes
121
122		type :: Electrostatic
123		integer :: c_ident
#	Line 84 | Line 125 | module electrostatic_module
125		logical :: is_Dipole = .false.
126		logical :: is_SplitDipole = .false.
127		logical :: is_Quadrupole = .false.
128	+	logical :: is_Tap = .false.
129		real(kind=DP) :: charge = 0.0_DP
130		real(kind=DP) :: dipole_moment = 0.0_DP
131		real(kind=DP) :: split_dipole_distance = 0.0_DP
#	Line 93 | Line 135 | contains
135		type(Electrostatic), dimension(:), allocatable :: ElectrostaticMap
136
137		contains
138	+
139	+	subroutine setElectrostaticSummationMethod(the_ESM)
140	+	integer, intent(in) :: the_ESM
141	+
142	+	if ((the_ESM .le. 0) .or. (the_ESM .gt. REACTION_FIELD)) then
143	+	call handleError("setElectrostaticSummationMethod", "Unsupported Summation Method")
144	+	endif
145	+
146	+	summationMethod = the_ESM
147	+
148	+	end subroutine setElectrostaticSummationMethod
149	+
150	+	subroutine setElectrostaticCutoffRadius(thisRcut, thisRsw)
151	+	real(kind=dp), intent(in) :: thisRcut
152	+	real(kind=dp), intent(in) :: thisRsw
153	+	defaultCutoff = thisRcut
154	+	rrf = defaultCutoff
155	+	rt = thisRsw
156	+	haveDefaultCutoff = .true.
157	+	end subroutine setElectrostaticCutoffRadius
158	+
159	+	subroutine setDampedWolfAlpha(thisAlpha)
160	+	real(kind=dp), intent(in) :: thisAlpha
161	+	dampingAlpha = thisAlpha
162	+	haveDampingAlpha = .true.
163	+	end subroutine setDampedWolfAlpha
164	+
165	+	subroutine setReactionFieldDielectric(thisDielectric)
166	+	real(kind=dp), intent(in) :: thisDielectric
167	+	dielectric = thisDielectric
168	+	haveDielectric = .true.
169	+	end subroutine setReactionFieldDielectric
170
171		subroutine newElectrostaticType(c_ident, is_Charge, is_Dipole, &
172	<	is_SplitDipole, is_Quadrupole, status)
173	<
172	>	is_SplitDipole, is_Quadrupole, is_Tap, status)
173	>
174		integer, intent(in) :: c_ident
175		logical, intent(in) :: is_Charge
176		logical, intent(in) :: is_Dipole
177		logical, intent(in) :: is_SplitDipole
178		logical, intent(in) :: is_Quadrupole
179	+	logical, intent(in) :: is_Tap
180		integer, intent(out) :: status
181		integer :: nAtypes, myATID, i, j
182
183		status = 0
184		myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
185	<
185	>
186		!! Be simple-minded and assume that we need an ElectrostaticMap that
187		!! is the same size as the total number of atom types
188
189		if (.not.allocated(ElectrostaticMap)) then
190	<
190	>
191		nAtypes = getSize(atypes)
192	<
192	>
193		if (nAtypes == 0) then
194		status = -1
195		return
196		end if
197	<
197	>
198		if (.not. allocated(ElectrostaticMap)) then
199		allocate(ElectrostaticMap(nAtypes))
200		endif
201	<
201	>
202		end if
203
204		if (myATID .gt. size(ElectrostaticMap)) then
205		status = -1
206		return
207		endif
208	<
208	>
209		! set the values for ElectrostaticMap for this atom type:
210
211		ElectrostaticMap(myATID)%c_ident = c_ident
#	Line 138 | Line 213 | contains
213		ElectrostaticMap(myATID)%is_Dipole = is_Dipole
214		ElectrostaticMap(myATID)%is_SplitDipole = is_SplitDipole
215		ElectrostaticMap(myATID)%is_Quadrupole = is_Quadrupole
216	<
216	>	ElectrostaticMap(myATID)%is_Tap = is_Tap
217	>
218		end subroutine newElectrostaticType
219
220		subroutine setCharge(c_ident, charge, status)
#	Line 166 | Line 242 | contains
242		call handleError("electrostatic", "Attempt to setCharge of an atom type that is not a charge!")
243		status = -1
244		return
245	<	endif
245	>	endif
246
247		ElectrostaticMap(myATID)%charge = charge
248		end subroutine setCharge
#	Line 257 | Line 333 | contains
333		status = -1
334		return
335		endif
336	<
336	>
337		do i = 1, 3
338	<	ElectrostaticMap(myATID)%quadrupole_moments(i) = &
339	<	quadrupole_moments(i)
340	<	enddo
338	>	ElectrostaticMap(myATID)%quadrupole_moments(i) = &
339	>	quadrupole_moments(i)
340	>	enddo
341
342		end subroutine setQuadrupoleMoments
343
344	<
344	>
345		function getCharge(atid) result (c)
346		integer, intent(in) :: atid
347		integer :: localError
348		real(kind=dp) :: c
349	<
349	>
350		if (.not.allocated(ElectrostaticMap)) then
351		call handleError("electrostatic", "no ElectrostaticMap was present before first call of getCharge!")
352		return
353		end if
354	<
354	>
355		if (.not.ElectrostaticMap(atid)%is_Charge) then
356		call handleError("electrostatic", "getCharge was called for an atom type that isn't a charge!")
357		return
358		endif
359	<
359	>
360		c = ElectrostaticMap(atid)%charge
361		end function getCharge
362
#	Line 288 | Line 364 | contains
364		integer, intent(in) :: atid
365		integer :: localError
366		real(kind=dp) :: dm
367	<
367	>
368		if (.not.allocated(ElectrostaticMap)) then
369		call handleError("electrostatic", "no ElectrostaticMap was present before first call of getDipoleMoment!")
370		return
371		end if
372	<
372	>
373		if (.not.ElectrostaticMap(atid)%is_Dipole) then
374		call handleError("electrostatic", "getDipoleMoment was called for an atom type that isn't a dipole!")
375		return
376		endif
377	<
377	>
378		dm = ElectrostaticMap(atid)%dipole_moment
379		end function getDipoleMoment
380
381	<	subroutine doElectrostaticPair(atom1, atom2, d, rij, r2, sw, &
382	<	vpair, fpair, pot, eFrame, f, t, do_pot)
383	<
381	>	subroutine checkSummationMethod()
382	>
383	>	if (.not.haveDefaultCutoff) then
384	>	call handleError("checkSummationMethod", "no Default Cutoff set!")
385	>	endif
386	>
387	>	rcuti = 1.0d0 / defaultCutoff
388	>	rcuti2 = rcuti*rcuti
389	>	rcuti3 = rcuti2*rcuti
390	>	rcuti4 = rcuti2*rcuti2
391	>
392	>	if (summationMethod .eq. DAMPED_WOLF) then
393	>	if (.not.haveDampingAlpha) then
394	>	call handleError("checkSummationMethod", "no Damping Alpha set!")
395	>	endif
396	>
397	>	if (.not.haveDefaultCutoff) then
398	>	call handleError("checkSummationMethod", "no Default Cutoff set!")
399	>	endif
400	>
401	>	constEXP = exp(-dampingAlpha*dampingAlpha*defaultCutoff*defaultCutoff)
402	>	constERFC = derfc(dampingAlpha*defaultCutoff)
403	>	invRootPi = 0.56418958354775628695d0
404	>	alphaPi = 2*dampingAlpha*invRootPi
405	>
406	>	endif
407	>
408	>	if (summationMethod .eq. REACTION_FIELD) then
409	>	if (haveDielectric) then
410	>	defaultCutoff2 = defaultCutoff*defaultCutoff
411	>	preRF = (dielectric-1.0d0) / &
412	>	((2.0d0*dielectric+1.0d0)*defaultCutoff2*defaultCutoff)
413	>	preRF2 = 2.0d0*preRF
414	>	else
415	>	call handleError("checkSummationMethod", "Dielectric not set")
416	>	endif
417	>
418	>	endif
419	>
420	>	summationMethodChecked = .true.
421	>	end subroutine checkSummationMethod
422	>
423	>	!!$
424	>	!!$  subroutine doElectrostaticPair(atom1, atom2, d, rij, r2, sw, &
425	>	!!$       vpair, fpair, pot, eFrame, f, t, do_pot)
426	>	subroutine doElectrostaticPair(atom1, atom2, d, rij, r2, sw, &
427	>	vpair, fpair, pot, eFrame, f, t, do_pot, felec)
428	>
429		logical, intent(in) :: do_pot
430	<
430	>
431		integer, intent(in) :: atom1, atom2
432		integer :: localError
433
434		real(kind=dp), intent(in) :: rij, r2, sw
435		real(kind=dp), intent(in), dimension(3) :: d
436		real(kind=dp), intent(inout) :: vpair
437	<	real(kind=dp), intent(inout), dimension(3) :: fpair
437	>	real(kind=dp), intent(inout), dimension(3) :: fpair
438	>	real(kind=dp), intent(inout), dimension(3) :: felec
439
440		real( kind = dp ) :: pot
441		real( kind = dp ), dimension(9,nLocal) :: eFrame
442		real( kind = dp ), dimension(3,nLocal) :: f
443		real( kind = dp ), dimension(3,nLocal) :: t
444	<
444	>
445		real (kind = dp), dimension(3) :: ux_i, uy_i, uz_i
446		real (kind = dp), dimension(3) :: ux_j, uy_j, uz_j
447		real (kind = dp), dimension(3) :: dudux_i, duduy_i, duduz_i
#	Line 327 | Line 449 | contains
449
450		logical :: i_is_Charge, i_is_Dipole, i_is_SplitDipole, i_is_Quadrupole
451		logical :: j_is_Charge, j_is_Dipole, j_is_SplitDipole, j_is_Quadrupole
452	+	logical :: i_is_Tap, j_is_Tap
453		integer :: me1, me2, id1, id2
454		real (kind=dp) :: q_i, q_j, mu_i, mu_j, d_i, d_j
455		real (kind=dp) :: qxx_i, qyy_i, qzz_i
#	Line 336 | Line 459 | contains
459		real (kind=dp) :: cx2, cy2, cz2
460		real (kind=dp) :: ct_i, ct_j, ct_ij, a1
461		real (kind=dp) :: riji, ri, ri2, ri3, ri4
462	<	real (kind=dp) :: pref, vterm, epot, dudr
462	>	real (kind=dp) :: pref, vterm, epot, dudr, vterm1, vterm2
463		real (kind=dp) :: xhat, yhat, zhat
464		real (kind=dp) :: dudx, dudy, dudz
342	–	real (kind=dp) :: drdxj, drdyj, drdzj
465		real (kind=dp) :: scale, sc2, bigR
466	+	real (kind=dp) :: varERFC, varEXP
467	+	real (kind=dp) :: limScale
468	+	real (kind=dp) :: preVal, rfVal
469
470		if (.not.allocated(ElectrostaticMap)) then
471		call handleError("electrostatic", "no ElectrostaticMap was present before first call of do_electrostatic_pair!")
472		return
473		end if
474
475	+	if (.not.summationMethodChecked) then
476	+	call checkSummationMethod()
477	+	endif
478	+
479		#ifdef IS_MPI
480		me1 = atid_Row(atom1)
481		me2 = atid_Col(atom2)
#	Line 358 | Line 487 | contains
487		!! some variables we'll need independent of electrostatic type:
488
489		riji = 1.0d0 / rij
490	<
490	>
491		xhat = d(1) * riji
492		yhat = d(2) * riji
493		zhat = d(3) * riji
494
366	–	drdxj = xhat
367	–	drdyj = yhat
368	–	drdzj = zhat
369	–
495		!! logicals
371	–
496		i_is_Charge = ElectrostaticMap(me1)%is_Charge
497		i_is_Dipole = ElectrostaticMap(me1)%is_Dipole
498		i_is_SplitDipole = ElectrostaticMap(me1)%is_SplitDipole
499		i_is_Quadrupole = ElectrostaticMap(me1)%is_Quadrupole
500	+	i_is_Tap = ElectrostaticMap(me1)%is_Tap
501
502		j_is_Charge = ElectrostaticMap(me2)%is_Charge
503		j_is_Dipole = ElectrostaticMap(me2)%is_Dipole
504		j_is_SplitDipole = ElectrostaticMap(me2)%is_SplitDipole
505		j_is_Quadrupole = ElectrostaticMap(me2)%is_Quadrupole
506	+	j_is_Tap = ElectrostaticMap(me2)%is_Tap
507
508		if (i_is_Charge) then
509		q_i = ElectrostaticMap(me1)%charge
510		endif
511	<
511	>
512		if (i_is_Dipole) then
513		mu_i = ElectrostaticMap(me1)%dipole_moment
514		#ifdef IS_MPI
#	Line 399 | Line 525 | contains
525		if (i_is_SplitDipole) then
526		d_i = ElectrostaticMap(me1)%split_dipole_distance
527		endif
528	<
528	>
529		endif
530
531		if (i_is_Quadrupole) then
#	Line 432 | Line 558 | contains
558		cz_i = uz_i(1)*xhat + uz_i(2)*yhat + uz_i(3)*zhat
559		endif
560
435	–
561		if (j_is_Charge) then
562		q_j = ElectrostaticMap(me2)%charge
563		endif
564	<
564	>
565		if (j_is_Dipole) then
566		mu_j = ElectrostaticMap(me2)%dipole_moment
567		#ifdef IS_MPI
#	Line 448 | Line 573 | contains
573		uz_j(2) = eFrame(6,atom2)
574		uz_j(3) = eFrame(9,atom2)
575		#endif
576	<	ct_j = uz_j(1)*drdxj + uz_j(2)*drdyj + uz_j(3)*drdzj
576	>	ct_j = uz_j(1)*xhat + uz_j(2)*yhat + uz_j(3)*zhat
577
578		if (j_is_SplitDipole) then
579		d_j = ElectrostaticMap(me2)%split_dipole_distance
#	Line 484 | Line 609 | contains
609		cy_j = uy_j(1)*xhat + uy_j(2)*yhat + uy_j(3)*zhat
610		cz_j = uz_j(1)*xhat + uz_j(2)*yhat + uz_j(3)*zhat
611		endif
612	<
612	>
613		epot = 0.0_dp
614		dudx = 0.0_dp
615		dudy = 0.0_dp
#	Line 501 | Line 626 | contains
626		if (i_is_Charge) then
627
628		if (j_is_Charge) then
504	–
505	–	vterm = pre11 * q_i * q_j * riji
506	–	vpair = vpair + vterm
507	–	epot = epot + sw*vterm
629
630	<	dudr  = - sw * vterm * riji
630	>	if (summationMethod .eq. UNDAMPED_WOLF) then
631	>	vterm = pre11 * q_i * q_j * (riji - rcuti)
632	>	vpair = vpair + vterm
633	>	epot = epot + sw*vterm
634	>
635	>	dudr  = -sw*pre11*q_i*q_j * (riji*riji-rcuti2)
636	>
637	>	dudx = dudx + dudr * xhat
638	>	dudy = dudy + dudr * yhat
639	>	dudz = dudz + dudr * zhat
640
641	<	dudx = dudx + dudr * drdxj
642	<	dudy = dudy + dudr * drdyj
643	<	dudz = dudz + dudr * drdzj
644	<
645	<	endif
641	>	elseif (summationMethod .eq. DAMPED_WOLF) then
642	>	varERFC = derfc(dampingAlpha*rij)
643	>	varEXP = exp(-dampingAlpha*dampingAlpha*rij*rij)
644	>	vterm = pre11 * q_i * q_j * (varERFC*riji - constERFC*rcuti)
645	>	vpair = vpair + vterm
646	>	epot = epot + sw*vterm
647	>
648	>	dudr  = -sw*pre11*q_i*q_j * (((varERFC*riji*riji &
649	>	+ alphaPi*varEXP*riji) - (constERFC*rcuti2 &
650	>	+ alphaPi*constEXP*rcuti)) )
651	>
652	>	dudx = dudx + dudr * xhat
653	>	dudy = dudy + dudr * yhat
654	>	dudz = dudz + dudr * zhat
655
656	<	if (j_is_Dipole) then
656	>	elseif (summationMethod .eq. REACTION_FIELD) then
657	>	preVal = pre11 * q_i * q_j
658	>	rfVal = preRF*rij*rij
659	>	vterm = preVal * ( riji + rfVal )
660	>
661	>	vpair = vpair + vterm
662	>	epot = epot + sw*vterm
663	>
664	>	dudr  = sw * preVal * ( 2.0d0*rfVal - riji )*riji
665	>
666	>	dudx = dudx + dudr * xhat
667	>	dudy = dudy + dudr * yhat
668	>	dudz = dudz + dudr * zhat
669
519	–	if (j_is_SplitDipole) then
520	–	BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
521	–	ri = 1.0_dp / BigR
522	–	scale = rij * ri
670		else
671	<	ri = riji
672	<	scale = 1.0_dp
671	>	vterm = pre11 * q_i * q_j * riji
672	>	vpair = vpair + vterm
673	>	epot = epot + sw*vterm
674	>
675	>	dudr  = - sw * vterm * riji
676	>
677	>	dudx = dudx + dudr * xhat
678	>	dudy = dudy + dudr * yhat
679	>	dudz = dudz + dudr * zhat
680	>
681		endif
682
683	<	ri2 = ri * ri
529	<	ri3 = ri2 * ri
530	<	sc2 = scale * scale
531	<
532	<	pref = pre12 * q_i * mu_j
533	<	vterm = - pref * ct_j * ri2 * scale
534	<	vpair = vpair + vterm
535	<	epot = epot + sw * vterm
683	>	endif
684
685	<	!! this has a + sign in the () because the rij vector is
538	<	!! r_j - r_i and the charge-dipole potential takes the origin
539	<	!! as the point dipole, which is atom j in this case.
685	>	if (j_is_Dipole) then
686
687	<	dudx = dudx - pref * sw * ri3 * ( uz_j(1) - 3.0d0*ct_j*xhat*sc2)
542	<	dudy = dudy - pref * sw * ri3 * ( uz_j(2) - 3.0d0*ct_j*yhat*sc2)
543	<	dudz = dudz - pref * sw * ri3 * ( uz_j(3) - 3.0d0*ct_j*zhat*sc2)
687	>	pref = pre12 * q_i * mu_j
688
689	<	duduz_j(1) = duduz_j(1) - pref * sw * ri2 * xhat * scale
690	<	duduz_j(2) = duduz_j(2) - pref * sw * ri2 * yhat * scale
691	<	duduz_j(3) = duduz_j(3) - pref * sw * ri2 * zhat * scale
692	<
689	>	if (summationMethod .eq. UNDAMPED_WOLF) then
690	>	ri2 = riji * riji
691	>	ri3 = ri2 * riji
692	>
693	>	pref = pre12 * q_i * mu_j
694	>	vterm = - pref * ct_j * (ri2 - rcuti2)
695	>	vpair = vpair + vterm
696	>	epot = epot + sw*vterm
697	>
698	>	!! this has a + sign in the () because the rij vector is
699	>	!! r_j - r_i and the charge-dipole potential takes the origin
700	>	!! as the point dipole, which is atom j in this case.
701	>
702	>	dudx = dudx - sw*pref * ( ri3*( uz_j(1) - 3.0d0*ct_j*xhat) &
703	>	- rcuti3*( uz_j(1) - 3.0d0*ct_j*d(1)*rcuti ) )
704	>	dudy = dudy - sw*pref * ( ri3*( uz_j(2) - 3.0d0*ct_j*yhat) &
705	>	- rcuti3*( uz_j(2) - 3.0d0*ct_j*d(2)*rcuti ) )
706	>	dudz = dudz - sw*pref * ( ri3*( uz_j(3) - 3.0d0*ct_j*zhat) &
707	>	- rcuti3*( uz_j(3) - 3.0d0*ct_j*d(3)*rcuti ) )
708	>
709	>	duduz_j(1) = duduz_j(1) - sw*pref*( ri2*xhat - d(1)*rcuti3 )
710	>	duduz_j(2) = duduz_j(2) - sw*pref*( ri2*yhat - d(2)*rcuti3 )
711	>	duduz_j(3) = duduz_j(3) - sw*pref*( ri2*zhat - d(3)*rcuti3 )
712	>
713	>	elseif (summationMethod .eq. REACTION_FIELD) then
714	>	ri2 = riji * riji
715	>	ri3 = ri2 * riji
716	>
717	>	pref = pre12 * q_i * mu_j
718	>	vterm = - pref * ct_j * ( ri2 - preRF2*rij )
719	>	vpair = vpair + vterm
720	>	epot = epot + sw*vterm
721	>
722	>	!! this has a + sign in the () because the rij vector is
723	>	!! r_j - r_i and the charge-dipole potential takes the origin
724	>	!! as the point dipole, which is atom j in this case.
725	>
726	>	dudx = dudx - sw*pref*( ri3*(uz_j(1) - 3.0d0*ct_j*xhat) - &
727	>	preRF2*uz_j(1) )
728	>	dudy = dudy - sw*pref*( ri3*(uz_j(2) - 3.0d0*ct_j*yhat) - &
729	>	preRF2*uz_j(2) )
730	>	dudz = dudz - sw*pref*( ri3*(uz_j(3) - 3.0d0*ct_j*zhat) - &
731	>	preRF2*uz_j(3) )
732	>	duduz_j(1) = duduz_j(1) - sw*pref * xhat * ( ri2 - preRF2*rij )
733	>	duduz_j(2) = duduz_j(2) - sw*pref * yhat * ( ri2 - preRF2*rij )
734	>	duduz_j(3) = duduz_j(3) - sw*pref * zhat * ( ri2 - preRF2*rij )
735	>
736	>	else
737	>	if (j_is_SplitDipole) then
738	>	BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
739	>	ri = 1.0_dp / BigR
740	>	scale = rij * ri
741	>	else
742	>	ri = riji
743	>	scale = 1.0_dp
744	>	endif
745	>
746	>	ri2 = ri * ri
747	>	ri3 = ri2 * ri
748	>	sc2 = scale * scale
749	>
750	>	pref = pre12 * q_i * mu_j
751	>	vterm = - pref * ct_j * ri2 * scale
752	>	vpair = vpair + vterm
753	>	epot = epot + sw*vterm
754	>
755	>	!! this has a + sign in the () because the rij vector is
756	>	!! r_j - r_i and the charge-dipole potential takes the origin
757	>	!! as the point dipole, which is atom j in this case.
758	>
759	>	dudx = dudx - sw*pref * ri3 * ( uz_j(1) - 3.0d0*ct_j*xhat*sc2)
760	>	dudy = dudy - sw*pref * ri3 * ( uz_j(2) - 3.0d0*ct_j*yhat*sc2)
761	>	dudz = dudz - sw*pref * ri3 * ( uz_j(3) - 3.0d0*ct_j*zhat*sc2)
762	>
763	>	duduz_j(1) = duduz_j(1) - sw*pref * ri2 * xhat * scale
764	>	duduz_j(2) = duduz_j(2) - sw*pref * ri2 * yhat * scale
765	>	duduz_j(3) = duduz_j(3) - sw*pref * ri2 * zhat * scale
766	>
767	>	endif
768		endif
769
770		if (j_is_Quadrupole) then
#	Line 556 | Line 775 | contains
775		cy2 = cy_j * cy_j
776		cz2 = cz_j * cz_j
777
778	<
779	<	pref =  pre14 * q_i / 1.0_dp
780	<	vterm = pref * ri3 * (qxx_j * (3.0_dp*cx2 - 1.0_dp) + &
781	<	qyy_j * (3.0_dp*cy2 - 1.0_dp) + &
782	<	qzz_j * (3.0_dp*cz2 - 1.0_dp))
783	<	vpair = vpair + vterm
784	<	epot = epot + sw * vterm
785	<
786	<	dudx = dudx - 5.0_dp*sw*vterm*riji*xhat - pref * sw * ri4 * ( &
787	<	qxx_j*(6.0_dp*cx_j*ux_j(1) - 2.0_dp*xhat) + &
788	<	qyy_j*(6.0_dp*cy_j*uy_j(1) - 2.0_dp*xhat) + &
789	<	qzz_j*(6.0_dp*cz_j*uz_j(1) - 2.0_dp*xhat) )
790	<	dudy = dudy - 5.0_dp*sw*vterm*riji*yhat - pref * sw * ri4 * ( &
791	<	qxx_j*(6.0_dp*cx_j*ux_j(2) - 2.0_dp*yhat) + &
792	<	qyy_j*(6.0_dp*cy_j*uy_j(2) - 2.0_dp*yhat) + &
793	<	qzz_j*(6.0_dp*cz_j*uz_j(2) - 2.0_dp*yhat) )
794	<	dudz = dudz - 5.0_dp*sw*vterm*riji*zhat - pref * sw * ri4 * ( &
795	<	qxx_j*(6.0_dp*cx_j*ux_j(3) - 2.0_dp*zhat) + &
796	<	qyy_j*(6.0_dp*cy_j*uy_j(3) - 2.0_dp*zhat) + &
797	<	qzz_j*(6.0_dp*cz_j*uz_j(3) - 2.0_dp*zhat) )
778	>	if (summationMethod .eq. UNDAMPED_WOLF) then
779	>	pref =  pre14 * q_i / 3.0_dp
780	>	vterm1 = pref * ri3*( qxx_j * (3.0_dp*cx2 - 1.0_dp) + &
781	>	qyy_j * (3.0_dp*cy2 - 1.0_dp) + &
782	>	qzz_j * (3.0_dp*cz2 - 1.0_dp) )
783	>	vterm2 = pref * rcuti3*( qxx_j * (3.0_dp*cx2 - 1.0_dp) + &
784	>	qyy_j * (3.0_dp*cy2 - 1.0_dp) + &
785	>	qzz_j * (3.0_dp*cz2 - 1.0_dp) )
786	>	vpair = vpair + ( vterm1 - vterm2 )
787	>	epot = epot + sw*( vterm1 - vterm2 )
788	>
789	>	dudx = dudx - (5.0_dp * &
790	>	(vterm1*riji*xhat - vterm2*rcuti2*d(1))) + sw*pref * ( &
791	>	(ri4 - rcuti4)*(qxx_j*(6.0_dp*cx_j*ux_j(1)) - &
792	>	qxx_j*2.0_dp*(xhat - rcuti*d(1))) + &
793	>	(ri4 - rcuti4)*(qyy_j*(6.0_dp*cy_j*uy_j(1)) - &
794	>	qyy_j*2.0_dp*(xhat - rcuti*d(1))) + &
795	>	(ri4 - rcuti4)*(qzz_j*(6.0_dp*cz_j*uz_j(1)) - &
796	>	qzz_j*2.0_dp*(xhat - rcuti*d(1))) )
797	>	dudy = dudy - (5.0_dp * &
798	>	(vterm1*riji*yhat - vterm2*rcuti2*d(2))) + sw*pref * ( &
799	>	(ri4 - rcuti4)*(qxx_j*(6.0_dp*cx_j*ux_j(2)) - &
800	>	qxx_j*2.0_dp*(yhat - rcuti*d(2))) + &
801	>	(ri4 - rcuti4)*(qyy_j*(6.0_dp*cy_j*uy_j(2)) - &
802	>	qyy_j*2.0_dp*(yhat - rcuti*d(2))) + &
803	>	(ri4 - rcuti4)*(qzz_j*(6.0_dp*cz_j*uz_j(2)) - &
804	>	qzz_j*2.0_dp*(yhat - rcuti*d(2))) )
805	>	dudz = dudz - (5.0_dp * &
806	>	(vterm1*riji*zhat - vterm2*rcuti2*d(3))) + sw*pref * ( &
807	>	(ri4 - rcuti4)*(qxx_j*(6.0_dp*cx_j*ux_j(3)) - &
808	>	qxx_j*2.0_dp*(zhat - rcuti*d(3))) + &
809	>	(ri4 - rcuti4)*(qyy_j*(6.0_dp*cy_j*uy_j(3)) - &
810	>	qyy_j*2.0_dp*(zhat - rcuti*d(3))) + &
811	>	(ri4 - rcuti4)*(qzz_j*(6.0_dp*cz_j*uz_j(3)) - &
812	>	qzz_j*2.0_dp*(zhat - rcuti*d(3))) )
813	>
814	>	dudux_j(1) = dudux_j(1) + sw*pref*(ri3*(qxx_j*6.0_dp*cx_j*xhat) -&
815	>	rcuti4*(qxx_j*6.0_dp*cx_j*d(1)))
816	>	dudux_j(2) = dudux_j(2) + sw*pref*(ri3*(qxx_j*6.0_dp*cx_j*yhat) -&
817	>	rcuti4*(qxx_j*6.0_dp*cx_j*d(2)))
818	>	dudux_j(3) = dudux_j(3) + sw*pref*(ri3*(qxx_j*6.0_dp*cx_j*zhat) -&
819	>	rcuti4*(qxx_j*6.0_dp*cx_j*d(3)))
820	>
821	>	duduy_j(1) = duduy_j(1) + sw*pref*(ri3*(qyy_j*6.0_dp*cy_j*xhat) -&
822	>	rcuti4*(qyy_j*6.0_dp*cx_j*d(1)))
823	>	duduy_j(2) = duduy_j(2) + sw*pref*(ri3*(qyy_j*6.0_dp*cy_j*yhat) -&
824	>	rcuti4*(qyy_j*6.0_dp*cx_j*d(2)))
825	>	duduy_j(3) = duduy_j(3) + sw*pref*(ri3*(qyy_j*6.0_dp*cy_j*zhat) -&
826	>	rcuti4*(qyy_j*6.0_dp*cx_j*d(3)))
827	>
828	>	duduz_j(1) = duduz_j(1) + sw*pref*(ri3*(qzz_j*6.0_dp*cz_j*xhat) -&
829	>	rcuti4*(qzz_j*6.0_dp*cx_j*d(1)))
830	>	duduz_j(2) = duduz_j(2) + sw*pref*(ri3*(qzz_j*6.0_dp*cz_j*yhat) -&
831	>	rcuti4*(qzz_j*6.0_dp*cx_j*d(2)))
832	>	duduz_j(3) = duduz_j(3) + sw*pref*(ri3*(qzz_j*6.0_dp*cz_j*zhat) -&
833	>	rcuti4*(qzz_j*6.0_dp*cx_j*d(3)))
834	>
835	>	else
836	>	pref =  pre14 * q_i / 3.0_dp
837	>	vterm = pref * ri3 * (qxx_j * (3.0_dp*cx2 - 1.0_dp) + &
838	>	qyy_j * (3.0_dp*cy2 - 1.0_dp) + &
839	>	qzz_j * (3.0_dp*cz2 - 1.0_dp))
840	>	vpair = vpair + vterm
841	>	epot = epot + sw*vterm
842	>
843	>	dudx = dudx - 5.0_dp*sw*vterm*riji*xhat + sw*pref * ri4 * ( &
844	>	qxx_j*(6.0_dp*cx_j*ux_j(1) - 2.0_dp*xhat) + &
845	>	qyy_j*(6.0_dp*cy_j*uy_j(1) - 2.0_dp*xhat) + &
846	>	qzz_j*(6.0_dp*cz_j*uz_j(1) - 2.0_dp*xhat) )
847	>	dudy = dudy - 5.0_dp*sw*vterm*riji*yhat + sw*pref * ri4 * ( &
848	>	qxx_j*(6.0_dp*cx_j*ux_j(2) - 2.0_dp*yhat) + &
849	>	qyy_j*(6.0_dp*cy_j*uy_j(2) - 2.0_dp*yhat) + &
850	>	qzz_j*(6.0_dp*cz_j*uz_j(2) - 2.0_dp*yhat) )
851	>	dudz = dudz - 5.0_dp*sw*vterm*riji*zhat + sw*pref * ri4 * ( &
852	>	qxx_j*(6.0_dp*cx_j*ux_j(3) - 2.0_dp*zhat) + &
853	>	qyy_j*(6.0_dp*cy_j*uy_j(3) - 2.0_dp*zhat) + &
854	>	qzz_j*(6.0_dp*cz_j*uz_j(3) - 2.0_dp*zhat) )
855	>
856	>	dudux_j(1) = dudux_j(1) + sw*pref * ri3*(qxx_j*6.0_dp*cx_j*xhat)
857	>	dudux_j(2) = dudux_j(2) + sw*pref * ri3*(qxx_j*6.0_dp*cx_j*yhat)
858	>	dudux_j(3) = dudux_j(3) + sw*pref * ri3*(qxx_j*6.0_dp*cx_j*zhat)
859	>
860	>	duduy_j(1) = duduy_j(1) + sw*pref * ri3*(qyy_j*6.0_dp*cy_j*xhat)
861	>	duduy_j(2) = duduy_j(2) + sw*pref * ri3*(qyy_j*6.0_dp*cy_j*yhat)
862	>	duduy_j(3) = duduy_j(3) + sw*pref * ri3*(qyy_j*6.0_dp*cy_j*zhat)
863	>
864	>	duduz_j(1) = duduz_j(1) + sw*pref * ri3*(qzz_j*6.0_dp*cz_j*xhat)
865	>	duduz_j(2) = duduz_j(2) + sw*pref * ri3*(qzz_j*6.0_dp*cz_j*yhat)
866	>	duduz_j(3) = duduz_j(3) + sw*pref * ri3*(qzz_j*6.0_dp*cz_j*zhat)
867
868	<	dudux_j(1) = dudux_j(1) + pref * sw * ri3 * (qxx_j*6.0_dp*cx_j*xhat)
581	<	dudux_j(2) = dudux_j(2) + pref * sw * ri3 * (qxx_j*6.0_dp*cx_j*yhat)
582	<	dudux_j(3) = dudux_j(3) + pref * sw * ri3 * (qxx_j*6.0_dp*cx_j*zhat)
583	<
584	<	duduy_j(1) = duduy_j(1) + pref * sw * ri3 * (qyy_j*6.0_dp*cy_j*xhat)
585	<	duduy_j(2) = duduy_j(2) + pref * sw * ri3 * (qyy_j*6.0_dp*cy_j*yhat)
586	<	duduy_j(3) = duduy_j(3) + pref * sw * ri3 * (qyy_j*6.0_dp*cy_j*zhat)
587	<
588	<	duduz_j(1) = duduz_j(1) + pref * sw * ri3 * (qzz_j*6.0_dp*cz_j*xhat)
589	<	duduz_j(2) = duduz_j(2) + pref * sw * ri3 * (qzz_j*6.0_dp*cz_j*yhat)
590	<	duduz_j(3) = duduz_j(3) + pref * sw * ri3 * (qzz_j*6.0_dp*cz_j*zhat)
868	>	endif
869		endif
592	–
870		endif
871	<
871	>
872		if (i_is_Dipole) then
873	<
873	>
874		if (j_is_Charge) then
875	+
876	+	pref = pre12 * q_j * mu_i
877	+
878	+	if (summationMethod .eq. UNDAMPED_WOLF) then
879	+	ri2 = riji * riji
880	+	ri3 = ri2 * riji
881
882	<	if (i_is_SplitDipole) then
883	<	BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
884	<	ri = 1.0_dp / BigR
885	<	scale = rij * ri
603	<	else
604	<	ri = riji
605	<	scale = 1.0_dp
606	<	endif
607	<
608	<	ri2 = ri * ri
609	<	ri3 = ri2 * ri
610	<	sc2 = scale * scale
882	>	pref = pre12 * q_j * mu_i
883	>	vterm = pref * ct_i * (ri2 - rcuti2)
884	>	vpair = vpair + vterm
885	>	epot = epot + sw*vterm
886
887	<	pref = pre12 * q_j * mu_i
888	<	vterm = pref * ct_i * ri2 * scale
889	<	vpair = vpair + vterm
890	<	epot = epot + sw * vterm
887	>	dudx = dudx + sw*pref * ( ri3*( uz_i(1) - 3.0d0*ct_i*xhat) &
888	>	- rcuti3*( uz_i(1) - 3.0d0*ct_i*d(1)*rcuti ) )
889	>	dudy = dudy + sw*pref * ( ri3*( uz_i(2) - 3.0d0*ct_i*yhat) &
890	>	- rcuti3*( uz_i(2) - 3.0d0*ct_i*d(2)*rcuti ) )
891	>	dudz = dudz + sw*pref * ( ri3*( uz_i(3) - 3.0d0*ct_i*zhat) &
892	>	- rcuti3*( uz_i(3) - 3.0d0*ct_i*d(3)*rcuti ) )
893	>
894	>	duduz_i(1) = duduz_i(1) + sw*pref*( ri2*xhat - d(1)*rcuti3 )
895	>	duduz_i(2) = duduz_i(2) + sw*pref*( ri2*yhat - d(2)*rcuti3 )
896	>	duduz_i(3) = duduz_i(3) + sw*pref*( ri2*zhat - d(3)*rcuti3 )
897
898	<	dudx = dudx + pref * sw * ri3 * ( uz_i(1) - 3.0d0 * ct_i * xhat*sc2)
899	<	dudy = dudy + pref * sw * ri3 * ( uz_i(2) - 3.0d0 * ct_i * yhat*sc2)
900	<	dudz = dudz + pref * sw * ri3 * ( uz_i(3) - 3.0d0 * ct_i * zhat*sc2)
898	>	elseif (summationMethod .eq. REACTION_FIELD) then
899	>	ri2 = riji * riji
900	>	ri3 = ri2 * riji
901
902	<	duduz_i(1) = duduz_i(1) + pref * sw * ri2 * xhat * scale
903	<	duduz_i(2) = duduz_i(2) + pref * sw * ri2 * yhat * scale
904	<	duduz_i(3) = duduz_i(3) + pref * sw * ri2 * zhat * scale
905	<	endif
902	>	pref = pre12 * q_j * mu_i
903	>	vterm = pref * ct_i * ( ri2 - preRF2*rij )
904	>	vpair = vpair + vterm
905	>	epot = epot + sw*vterm
906	>
907	>	dudx = dudx + sw*pref * ( ri3*(uz_i(1) - 3.0d0*ct_i*xhat) - &
908	>	preRF2*uz_i(1) )
909	>	dudy = dudy + sw*pref * ( ri3*(uz_i(2) - 3.0d0*ct_i*yhat) - &
910	>	preRF2*uz_i(2) )
911	>	dudz = dudz + sw*pref * ( ri3*(uz_i(3) - 3.0d0*ct_i*zhat) - &
912	>	preRF2*uz_i(3) )
913	>
914	>	duduz_i(1) = duduz_i(1) + sw*pref * xhat * ( ri2 - preRF2*rij )
915	>	duduz_i(2) = duduz_i(2) + sw*pref * yhat * ( ri2 - preRF2*rij )
916	>	duduz_i(3) = duduz_i(3) + sw*pref * zhat * ( ri2 - preRF2*rij )
917
918	<	if (j_is_Dipole) then
919	<
628	<	if (i_is_SplitDipole) then
629	<	if (j_is_SplitDipole) then
630	<	BigR = sqrt(r2 + 0.25_dp * d_i * d_i + 0.25_dp * d_j * d_j)
631	<	else
918	>	else
919	>	if (i_is_SplitDipole) then
920		BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
921	<	endif
922	<	ri = 1.0_dp / BigR
923	<	scale = rij * ri
636	<	else
637	<	if (j_is_SplitDipole) then
638	<	BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
639	<	ri = 1.0_dp / BigR
640	<	scale = rij * ri
641	<	else
921	>	ri = 1.0_dp / BigR
922	>	scale = rij * ri
923	>	else
924		ri = riji
925		scale = 1.0_dp
926		endif
927	+
928	+	ri2 = ri * ri
929	+	ri3 = ri2 * ri
930	+	sc2 = scale * scale
931	+
932	+	pref = pre12 * q_j * mu_i
933	+	vterm = pref * ct_i * ri2 * scale
934	+	vpair = vpair + vterm
935	+	epot = epot + sw*vterm
936	+
937	+	dudx = dudx + sw*pref * ri3 * ( uz_i(1) - 3.0d0 * ct_i * xhat*sc2)
938	+	dudy = dudy + sw*pref * ri3 * ( uz_i(2) - 3.0d0 * ct_i * yhat*sc2)
939	+	dudz = dudz + sw*pref * ri3 * ( uz_i(3) - 3.0d0 * ct_i * zhat*sc2)
940	+
941	+	duduz_i(1) = duduz_i(1) + sw*pref * ri2 * xhat * scale
942	+	duduz_i(2) = duduz_i(2) + sw*pref * ri2 * yhat * scale
943	+	duduz_i(3) = duduz_i(3) + sw*pref * ri2 * zhat * scale
944		endif
945	+	endif
946	+
947	+	if (j_is_Dipole) then
948
949	<	ct_ij = uz_i(1)*uz_j(1) + uz_i(2)*uz_j(2) + uz_i(3)*uz_j(3)
950	<
951	<	ri2 = ri * ri
952	<	ri3 = ri2 * ri
953	<	ri4 = ri2 * ri2
954	<	sc2 = scale * scale
955	<
956	<	pref = pre22 * mu_i * mu_j
957	<	vterm = pref * ri3 * (ct_ij - 3.0d0 * ct_i * ct_j * sc2)
958	<	vpair = vpair + vterm
959	<	epot = epot + sw * vterm
949	>	if (summationMethod .eq. UNDAMPED_WOLF) then
950	>	!!$             ct_ij = uz_i(1)*uz_j(1) + uz_i(2)*uz_j(2) + uz_i(3)*uz_j(3)
951	>	!!$
952	>	!!$             ri2 = riji * riji
953	>	!!$             ri3 = ri2 * riji
954	>	!!$             ri4 = ri2 * ri2
955	>	!!$
956	>	!!$             pref = pre22 * mu_i * mu_j
957	>	!!$             vterm = pref * (ri3 - rcuti3) * (ct_ij - 3.0d0 * ct_i * ct_j)
958	>	!!$             vpair = vpair + vterm
959	>	!!$             epot = epot + sw*vterm
960	>	!!$
961	>	!!$             a1 = 5.0d0 * ct_i * ct_j - ct_ij
962	>	!!$
963	>	!!$             dudx = dudx + sw*pref*3.0d0*( &
964	>	!!$                  ri4*(a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1)) &
965	>	!!$                  - rcuti4*(a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1)) )
966	>	!!$             dudy = dudy + sw*pref*3.0d0*( &
967	>	!!$                  ri4*(a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2)) &
968	>	!!$                  - rcuti4*(a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2)) )
969	>	!!$             dudz = dudz + sw*pref*3.0d0*( &
970	>	!!$                  ri4*(a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3)) &
971	>	!!$                  - rcuti4*(a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3)) )
972	>	!!$
973	>	!!$             duduz_i(1) = duduz_i(1) + sw*pref*(ri3*(uz_j(1)-3.0d0*ct_j*xhat) &
974	>	!!$                  - rcuti3*(uz_j(1) - 3.0d0*ct_j*xhat))
975	>	!!$             duduz_i(2) = duduz_i(2) + sw*pref*(ri3*(uz_j(2)-3.0d0*ct_j*yhat) &
976	>	!!$                  - rcuti3*(uz_j(2) - 3.0d0*ct_j*yhat))
977	>	!!$             duduz_i(3) = duduz_i(3) + sw*pref*(ri3*(uz_j(3)-3.0d0*ct_j*zhat) &
978	>	!!$                  - rcuti3*(uz_j(3) - 3.0d0*ct_j*zhat))
979	>	!!$             duduz_j(1) = duduz_j(1) + sw*pref*(ri3*(uz_i(1)-3.0d0*ct_i*xhat) &
980	>	!!$                  - rcuti3*(uz_i(1) - 3.0d0*ct_i*xhat))
981	>	!!$             duduz_j(2) = duduz_j(2) + sw*pref*(ri3*(uz_i(2)-3.0d0*ct_i*yhat) &
982	>	!!$                  - rcuti3*(uz_i(2) - 3.0d0*ct_i*yhat))
983	>	!!$             duduz_j(3) = duduz_j(3) + sw*pref*(ri3*(uz_i(3)-3.0d0*ct_i*zhat) &
984	>	!!$                  - rcuti3*(uz_i(3) - 3.0d0*ct_i*zhat))
985
986	<	a1 = 5.0d0 * ct_i * ct_j * sc2 - ct_ij
986	>	elseif (summationMethod .eq. DAMPED_WOLF) then
987	>	ct_ij = uz_i(1)*uz_j(1) + uz_i(2)*uz_j(2) + uz_i(3)*uz_j(3)
988	>
989	>	ri2 = riji * riji
990	>	ri3 = ri2 * riji
991	>	ri4 = ri2 * ri2
992	>	sc2 = scale * scale
993	>
994	>	pref = pre22 * mu_i * mu_j
995	>	vterm = pref * ri3 * (ct_ij - 3.0d0 * ct_i * ct_j)
996	>	vpair = vpair + vterm
997	>	epot = epot + sw*vterm
998	>
999	>	a1 = 5.0d0 * ct_i * ct_j * sc2 - ct_ij
1000	>
1001	>	dudx = dudx + sw*pref*3.0d0*ri4*(a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1))
1002	>	dudy = dudy + sw*pref*3.0d0*ri4*(a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2))
1003	>	dudz = dudz + sw*pref*3.0d0*ri4*(a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3))
1004	>
1005	>	duduz_i(1) = duduz_i(1) + sw*pref*ri3 *(uz_j(1) - 3.0d0*ct_j*xhat)
1006	>	duduz_i(2) = duduz_i(2) + sw*pref*ri3 *(uz_j(2) - 3.0d0*ct_j*yhat)
1007	>	duduz_i(3) = duduz_i(3) + sw*pref*ri3 *(uz_j(3) - 3.0d0*ct_j*zhat)
1008	>
1009	>	duduz_j(1) = duduz_j(1) + sw*pref*ri3 *(uz_i(1) - 3.0d0*ct_i*xhat)
1010	>	duduz_j(2) = duduz_j(2) + sw*pref*ri3 *(uz_i(2) - 3.0d0*ct_i*yhat)
1011	>	duduz_j(3) = duduz_j(3) + sw*pref*ri3 *(uz_i(3) - 3.0d0*ct_i*zhat)
1012	>
1013	>	elseif (summationMethod .eq. REACTION_FIELD) then
1014	>	ct_ij = uz_i(1)*uz_j(1) + uz_i(2)*uz_j(2) + uz_i(3)*uz_j(3)
1015
1016	<	dudx=dudx+pref*sw*3.0d0*ri4*scale*(a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1))
1017	<	dudy=dudy+pref*sw*3.0d0*ri4*scale*(a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2))
1018	<	dudz=dudz+pref*sw*3.0d0*ri4*scale*(a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3))
1016	>	ri2 = riji * riji
1017	>	ri3 = ri2 * riji
1018	>	ri4 = ri2 * ri2
1019
1020	<	duduz_i(1) = duduz_i(1) + pref*sw*ri3*(uz_j(1) - 3.0d0*ct_j*xhat*sc2)
1021	<	duduz_i(2) = duduz_i(2) + pref*sw*ri3*(uz_j(2) - 3.0d0*ct_j*yhat*sc2)
1022	<	duduz_i(3) = duduz_i(3) + pref*sw*ri3*(uz_j(3) - 3.0d0*ct_j*zhat*sc2)
1020	>	pref = pre22 * mu_i * mu_j
1021	>
1022	>	vterm = pref*( ri3*(ct_ij - 3.0d0 * ct_i * ct_j) - &
1023	>	preRF2*ct_ij )
1024	>	vpair = vpair + vterm
1025	>	epot = epot + sw*vterm
1026	>
1027	>	a1 = 5.0d0 * ct_i * ct_j - ct_ij
1028	>
1029	>	dudx = dudx + sw*pref*3.0d0*ri4 &
1030	>	* (a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1))
1031	>	dudy = dudy + sw*pref*3.0d0*ri4 &
1032	>	* (a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2))
1033	>	dudz = dudz + sw*pref*3.0d0*ri4 &
1034	>	* (a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3))
1035	>
1036	>	duduz_i(1) = duduz_i(1) + sw*pref*(ri3*(uz_j(1)-3.0d0*ct_j*xhat) &
1037	>	- preRF2*uz_j(1))
1038	>	duduz_i(2) = duduz_i(2) + sw*pref*(ri3*(uz_j(2)-3.0d0*ct_j*yhat) &
1039	>	- preRF2*uz_j(2))
1040	>	duduz_i(3) = duduz_i(3) + sw*pref*(ri3*(uz_j(3)-3.0d0*ct_j*zhat) &
1041	>	- preRF2*uz_j(3))
1042	>	duduz_j(1) = duduz_j(1) + sw*pref*(ri3*(uz_i(1)-3.0d0*ct_i*xhat) &
1043	>	- preRF2*uz_i(1))
1044	>	duduz_j(2) = duduz_j(2) + sw*pref*(ri3*(uz_i(2)-3.0d0*ct_i*yhat) &
1045	>	- preRF2*uz_i(2))
1046	>	duduz_j(3) = duduz_j(3) + sw*pref*(ri3*(uz_i(3)-3.0d0*ct_i*zhat) &
1047	>	- preRF2*uz_i(3))
1048
1049	<	duduz_j(1) = duduz_j(1) + pref*sw*ri3*(uz_i(1) - 3.0d0*ct_i*xhat*sc2)
1050	<	duduz_j(2) = duduz_j(2) + pref*sw*ri3*(uz_i(2) - 3.0d0*ct_i*yhat*sc2)
1051	<	duduz_j(3) = duduz_j(3) + pref*sw*ri3*(uz_i(3) - 3.0d0*ct_i*zhat*sc2)
1049	>	else
1050	>	if (i_is_SplitDipole) then
1051	>	if (j_is_SplitDipole) then
1052	>	BigR = sqrt(r2 + 0.25_dp * d_i * d_i + 0.25_dp * d_j * d_j)
1053	>	else
1054	>	BigR = sqrt(r2 + 0.25_dp * d_i * d_i)
1055	>	endif
1056	>	ri = 1.0_dp / BigR
1057	>	scale = rij * ri
1058	>	else
1059	>	if (j_is_SplitDipole) then
1060	>	BigR = sqrt(r2 + 0.25_dp * d_j * d_j)
1061	>	ri = 1.0_dp / BigR
1062	>	scale = rij * ri
1063	>	else
1064	>	ri = riji
1065	>	scale = 1.0_dp
1066	>	endif
1067	>	endif
1068	>
1069	>	ct_ij = uz_i(1)*uz_j(1) + uz_i(2)*uz_j(2) + uz_i(3)*uz_j(3)
1070	>
1071	>	ri2 = ri * ri
1072	>	ri3 = ri2 * ri
1073	>	ri4 = ri2 * ri2
1074	>	sc2 = scale * scale
1075	>
1076	>	pref = pre22 * mu_i * mu_j
1077	>	vterm = pref * ri3 * (ct_ij - 3.0d0 * ct_i * ct_j * sc2)
1078	>	vpair = vpair + vterm
1079	>	epot = epot + sw*vterm
1080	>
1081	>	a1 = 5.0d0 * ct_i * ct_j * sc2 - ct_ij
1082	>
1083	>	dudx = dudx + sw*pref*3.0d0*ri4*scale &
1084	>	*(a1*xhat-ct_i*uz_j(1)-ct_j*uz_i(1))
1085	>	dudy = dudy + sw*pref*3.0d0*ri4*scale &
1086	>	*(a1*yhat-ct_i*uz_j(2)-ct_j*uz_i(2))
1087	>	dudz = dudz + sw*pref*3.0d0*ri4*scale &
1088	>	*(a1*zhat-ct_i*uz_j(3)-ct_j*uz_i(3))
1089	>
1090	>	duduz_i(1) = duduz_i(1) + sw*pref*ri3 &
1091	>	*(uz_j(1) - 3.0d0*ct_j*xhat*sc2)
1092	>	duduz_i(2) = duduz_i(2) + sw*pref*ri3 &
1093	>	*(uz_j(2) - 3.0d0*ct_j*yhat*sc2)
1094	>	duduz_i(3) = duduz_i(3) + sw*pref*ri3 &
1095	>	*(uz_j(3) - 3.0d0*ct_j*zhat*sc2)
1096	>
1097	>	duduz_j(1) = duduz_j(1) + sw*pref*ri3 &
1098	>	*(uz_i(1) - 3.0d0*ct_i*xhat*sc2)
1099	>	duduz_j(2) = duduz_j(2) + sw*pref*ri3 &
1100	>	*(uz_i(2) - 3.0d0*ct_i*yhat*sc2)
1101	>	duduz_j(3) = duduz_j(3) + sw*pref*ri3 &
1102	>	*(uz_i(3) - 3.0d0*ct_i*zhat*sc2)
1103	>	endif
1104		endif
673	–
1105		endif
1106
1107		if (i_is_Quadrupole) then
1108		if (j_is_Charge) then
1109	<
1109	>
1110		ri2 = riji * riji
1111		ri3 = ri2 * riji
1112		ri4 = ri2 * ri2
1113		cx2 = cx_i * cx_i
1114		cy2 = cy_i * cy_i
1115		cz2 = cz_i * cz_i
1116	<
1117	<	pref = pre14 * q_j / 1.0_dp
1118	<	vterm = pref * ri3 * (qxx_i * (3.0_dp*cx2 - 1.0_dp) + &
1119	<	qyy_i * (3.0_dp*cy2 - 1.0_dp) + &
1120	<	qzz_i * (3.0_dp*cz2 - 1.0_dp))
1121	<	vpair = vpair + vterm
1122	<	epot = epot + sw * vterm
1123	<
1124	<	dudx = dudx - 5.0_dp*sw*vterm*riji*xhat - pref * sw * ri4 * ( &
1125	<	qxx_i*(6.0_dp*cx_i*ux_i(1) - 2.0_dp*xhat) + &
1126	<	qyy_i*(6.0_dp*cy_i*uy_i(1) - 2.0_dp*xhat) + &
1127	<	qzz_i*(6.0_dp*cz_i*uz_i(1) - 2.0_dp*xhat) )
1128	<	dudy = dudy - 5.0_dp*sw*vterm*riji*yhat - pref * sw * ri4 * ( &
1129	<	qxx_i*(6.0_dp*cx_i*ux_i(2) - 2.0_dp*yhat) + &
1130	<	qyy_i*(6.0_dp*cy_i*uy_i(2) - 2.0_dp*yhat) + &
1131	<	qzz_i*(6.0_dp*cz_i*uz_i(2) - 2.0_dp*yhat) )
1132	<	dudz = dudz - 5.0_dp*sw*vterm*riji*zhat - pref * sw * ri4 * ( &
1133	<	qxx_i*(6.0_dp*cx_i*ux_i(3) - 2.0_dp*zhat) + &
1134	<	qyy_i*(6.0_dp*cy_i*uy_i(3) - 2.0_dp*zhat) + &
1135	<	qzz_i*(6.0_dp*cz_i*uz_i(3) - 2.0_dp*zhat) )
1136	<
1137	<	dudux_i(1) = dudux_i(1) + pref * sw * ri3 * (qxx_i*6.0_dp*cx_i*xhat)
1138	<	dudux_i(2) = dudux_i(2) + pref * sw * ri3 * (qxx_i*6.0_dp*cx_i*yhat)
1139	<	dudux_i(3) = dudux_i(3) + pref * sw * ri3 * (qxx_i*6.0_dp*cx_i*zhat)
1140	<
1141	<	duduy_i(1) = duduy_i(1) + pref * sw * ri3 * (qyy_i*6.0_dp*cy_i*xhat)
1142	<	duduy_i(2) = duduy_i(2) + pref * sw * ri3 * (qyy_i*6.0_dp*cy_i*yhat)
1143	<	duduy_i(3) = duduy_i(3) + pref * sw * ri3 * (qyy_i*6.0_dp*cy_i*zhat)
1144	<
1145	<	duduz_i(1) = duduz_i(1) + pref * sw * ri3 * (qzz_i*6.0_dp*cz_i*xhat)
1146	<	duduz_i(2) = duduz_i(2) + pref * sw * ri3 * (qzz_i*6.0_dp*cz_i*yhat)
1147	<	duduz_i(3) = duduz_i(3) + pref * sw * ri3 * (qzz_i*6.0_dp*cz_i*zhat)
1116	>
1117	>	if (summationMethod .eq. UNDAMPED_WOLF) then
1118	>	pref = pre14 * q_j / 3.0_dp
1119	>	vterm1 = pref * ri3*( qxx_i * (3.0_dp*cx2 - 1.0_dp) + &
1120	>	qyy_i * (3.0_dp*cy2 - 1.0_dp) + &
1121	>	qzz_i * (3.0_dp*cz2 - 1.0_dp) )
1122	>	vterm2 = pref * rcuti3*( qxx_i * (3.0_dp*cx2 - 1.0_dp) + &
1123	>	qyy_i * (3.0_dp*cy2 - 1.0_dp) + &
1124	>	qzz_i * (3.0_dp*cz2 - 1.0_dp) )
1125	>	vpair = vpair + ( vterm1 - vterm2 )
1126	>	epot = epot + sw*( vterm1 - vterm2 )
1127	>
1128	>	dudx = dudx - sw*(5.0_dp*(vterm1*riji*xhat-vterm2*rcuti2*d(1))) +&
1129	>	sw*pref * ( (ri4 - rcuti4)*(qxx_i*(6.0_dp*cx_i*ux_i(1)) - &
1130	>	qxx_i*2.0_dp*(xhat - rcuti*d(1))) + &
1131	>	(ri4 - rcuti4)*(qyy_i*(6.0_dp*cy_i*uy_i(1)) - &
1132	>	qyy_i*2.0_dp*(xhat - rcuti*d(1))) + &
1133	>	(ri4 - rcuti4)*(qzz_i*(6.0_dp*cz_i*uz_i(1)) - &
1134	>	qzz_i*2.0_dp*(xhat - rcuti*d(1))) )
1135	>	dudy = dudy - sw*(5.0_dp*(vterm1*riji*yhat-vterm2*rcuti2*d(2))) +&
1136	>	sw*pref * ( (ri4 - rcuti4)*(qxx_i*(6.0_dp*cx_i*ux_i(2)) - &
1137	>	qxx_i*2.0_dp*(yhat - rcuti*d(2))) + &
1138	>	(ri4 - rcuti4)*(qyy_i*(6.0_dp*cy_i*uy_i(2)) - &
1139	>	qyy_i*2.0_dp*(yhat - rcuti*d(2))) + &
1140	>	(ri4 - rcuti4)*(qzz_i*(6.0_dp*cz_i*uz_i(2)) - &
1141	>	qzz_i*2.0_dp*(yhat - rcuti*d(2))) )
1142	>	dudz = dudz - sw*(5.0_dp*(vterm1*riji*zhat-vterm2*rcuti2*d(3))) +&
1143	>	sw*pref * ( (ri4 - rcuti4)*(qxx_i*(6.0_dp*cx_i*ux_i(3)) - &
1144	>	qxx_i*2.0_dp*(zhat - rcuti*d(3))) + &
1145	>	(ri4 - rcuti4)*(qyy_i*(6.0_dp*cy_i*uy_i(3)) - &
1146	>	qyy_i*2.0_dp*(zhat - rcuti*d(3))) + &
1147	>	(ri4 - rcuti4)*(qzz_i*(6.0_dp*cz_i*uz_i(3)) - &
1148	>	qzz_i*2.0_dp*(zhat - rcuti*d(3))) )
1149	>
1150	>	dudux_i(1) = dudux_i(1) + sw*pref*(ri3*(qxx_i*6.0_dp*cx_i*xhat) -&
1151	>	rcuti4*(qxx_i*6.0_dp*cx_i*d(1)))
1152	>	dudux_i(2) = dudux_i(2) + sw*pref*(ri3*(qxx_i*6.0_dp*cx_i*yhat) -&
1153	>	rcuti4*(qxx_i*6.0_dp*cx_i*d(2)))
1154	>	dudux_i(3) = dudux_i(3) + sw*pref*(ri3*(qxx_i*6.0_dp*cx_i*zhat) -&
1155	>	rcuti4*(qxx_i*6.0_dp*cx_i*d(3)))
1156	>
1157	>	duduy_i(1) = duduy_i(1) + sw*pref*(ri3*(qyy_i*6.0_dp*cy_i*xhat) -&
1158	>	rcuti4*(qyy_i*6.0_dp*cx_i*d(1)))
1159	>	duduy_i(2) = duduy_i(2) + sw*pref*(ri3*(qyy_i*6.0_dp*cy_i*yhat) -&
1160	>	rcuti4*(qyy_i*6.0_dp*cx_i*d(2)))
1161	>	duduy_i(3) = duduy_i(3) + sw*pref*(ri3*(qyy_i*6.0_dp*cy_i*zhat) -&
1162	>	rcuti4*(qyy_i*6.0_dp*cx_i*d(3)))
1163	>
1164	>	duduz_i(1) = duduz_i(1) + sw*pref*(ri3*(qzz_i*6.0_dp*cz_i*xhat) -&
1165	>	rcuti4*(qzz_i*6.0_dp*cx_i*d(1)))
1166	>	duduz_i(2) = duduz_i(2) + sw*pref*(ri3*(qzz_i*6.0_dp*cz_i*yhat) -&
1167	>	rcuti4*(qzz_i*6.0_dp*cx_i*d(2)))
1168	>	duduz_i(3) = duduz_i(3) + sw*pref*(ri3*(qzz_i*6.0_dp*cz_i*zhat) -&
1169	>	rcuti4*(qzz_i*6.0_dp*cx_i*d(3)))
1170	>
1171	>	else
1172	>	pref = pre14 * q_j / 3.0_dp
1173	>	vterm = pref * ri3 * (qxx_i * (3.0_dp*cx2 - 1.0_dp) + &
1174	>	qyy_i * (3.0_dp*cy2 - 1.0_dp) + &
1175	>	qzz_i * (3.0_dp*cz2 - 1.0_dp))
1176	>	vpair = vpair + vterm
1177	>	epot = epot + sw*vterm
1178	>
1179	>	dudx = dudx - 5.0_dp*sw*vterm*riji*xhat + sw*pref*ri4 * ( &
1180	>	qxx_i*(6.0_dp*cx_i*ux_i(1) - 2.0_dp*xhat) + &
1181	>	qyy_i*(6.0_dp*cy_i*uy_i(1) - 2.0_dp*xhat) + &
1182	>	qzz_i*(6.0_dp*cz_i*uz_i(1) - 2.0_dp*xhat) )
1183	>	dudy = dudy - 5.0_dp*sw*vterm*riji*yhat + sw*pref*ri4 * ( &
1184	>	qxx_i*(6.0_dp*cx_i*ux_i(2) - 2.0_dp*yhat) + &
1185	>	qyy_i*(6.0_dp*cy_i*uy_i(2) - 2.0_dp*yhat) + &
1186	>	qzz_i*(6.0_dp*cz_i*uz_i(2) - 2.0_dp*yhat) )
1187	>	dudz = dudz - 5.0_dp*sw*vterm*riji*zhat + sw*pref*ri4 * ( &
1188	>	qxx_i*(6.0_dp*cx_i*ux_i(3) - 2.0_dp*zhat) + &
1189	>	qyy_i*(6.0_dp*cy_i*uy_i(3) - 2.0_dp*zhat) + &
1190	>	qzz_i*(6.0_dp*cz_i*uz_i(3) - 2.0_dp*zhat) )
1191	>
1192	>	dudux_i(1) = dudux_i(1) + sw*pref*ri3*(qxx_i*6.0_dp*cx_i*xhat)
1193	>	dudux_i(2) = dudux_i(2) + sw*pref*ri3*(qxx_i*6.0_dp*cx_i*yhat)
1194	>	dudux_i(3) = dudux_i(3) + sw*pref*ri3*(qxx_i*6.0_dp*cx_i*zhat)
1195	>
1196	>	duduy_i(1) = duduy_i(1) + sw*pref*ri3*(qyy_i*6.0_dp*cy_i*xhat)
1197	>	duduy_i(2) = duduy_i(2) + sw*pref*ri3*(qyy_i*6.0_dp*cy_i*yhat)
1198	>	duduy_i(3) = duduy_i(3) + sw*pref*ri3*(qyy_i*6.0_dp*cy_i*zhat)
1199	>
1200	>	duduz_i(1) = duduz_i(1) + sw*pref*ri3*(qzz_i*6.0_dp*cz_i*xhat)
1201	>	duduz_i(2) = duduz_i(2) + sw*pref*ri3*(qzz_i*6.0_dp*cz_i*yhat)
1202	>	duduz_i(3) = duduz_i(3) + sw*pref*ri3*(qzz_i*6.0_dp*cz_i*zhat)
1203	>	endif
1204		endif
1205		endif
1206	<
1207	<
1206	>
1207	>
1208		if (do_pot) then
1209		#ifdef IS_MPI
1210	<	pot_row(atom1) = pot_row(atom1) + 0.5d0*epot
1211	<	pot_col(atom2) = pot_col(atom2) + 0.5d0*epot
1210	>	pot_row(ELECTROSTATIC_POT,atom1) = pot_row(ELECTROSTATIC_POT,atom1) + 0.5d0*epot
1211	>	pot_col(ELECTROSTATIC_POT,atom2) = pot_col(ELECTROSTATIC_POT,atom2) + 0.5d0*epot
1212		#else
1213		pot = pot + epot
1214		#endif
1215		endif
1216	<
1216	>
1217		#ifdef IS_MPI
1218		f_Row(1,atom1) = f_Row(1,atom1) + dudx
1219		f_Row(2,atom1) = f_Row(2,atom1) + dudy
1220		f_Row(3,atom1) = f_Row(3,atom1) + dudz
1221	<
1221	>
1222		f_Col(1,atom2) = f_Col(1,atom2) - dudx
1223		f_Col(2,atom2) = f_Col(2,atom2) - dudy
1224		f_Col(3,atom2) = f_Col(3,atom2) - dudz
1225	<
1225	>
1226		if (i_is_Dipole .or. i_is_Quadrupole) then
1227		t_Row(1,atom1)=t_Row(1,atom1) - uz_i(2)*duduz_i(3) + uz_i(3)*duduz_i(2)
1228		t_Row(2,atom1)=t_Row(2,atom1) - uz_i(3)*duduz_i(1) + uz_i(1)*duduz_i(3)
#	Line 770 | Line 1257 | contains
1257		f(1,atom1) = f(1,atom1) + dudx
1258		f(2,atom1) = f(2,atom1) + dudy
1259		f(3,atom1) = f(3,atom1) + dudz
1260	<
1260	>
1261		f(1,atom2) = f(1,atom2) - dudx
1262		f(2,atom2) = f(2,atom2) - dudy
1263		f(3,atom2) = f(3,atom2) - dudz
1264	<
1264	>
1265		if (i_is_Dipole .or. i_is_Quadrupole) then
1266		t(1,atom1)=t(1,atom1) - uz_i(2)*duduz_i(3) + uz_i(3)*duduz_i(2)
1267		t(2,atom1)=t(2,atom1) - uz_i(3)*duduz_i(1) + uz_i(1)*duduz_i(3)
#	Line 806 | Line 1293 | contains
1293		endif
1294
1295		#endif
1296	<
1296	>
1297		#ifdef IS_MPI
1298		id1 = AtomRowToGlobal(atom1)
1299		id2 = AtomColToGlobal(atom2)
#	Line 816 | Line 1303 | contains
1303		#endif
1304
1305		if (molMembershipList(id1) .ne. molMembershipList(id2)) then
1306	<
1306	>
1307		fpair(1) = fpair(1) + dudx
1308		fpair(2) = fpair(2) + dudy
1309		fpair(3) = fpair(3) + dudz
#	Line 825 | Line 1312 | contains
1312
1313		return
1314		end subroutine doElectrostaticPair
1315	<
1315	>
1316	>	subroutine destroyElectrostaticTypes()
1317	>
1318	>	if(allocated(ElectrostaticMap)) deallocate(ElectrostaticMap)
1319	>
1320	>	end subroutine destroyElectrostaticTypes
1321	>
1322	>	subroutine self_self(atom1, eFrame, mypot, t, do_pot)
1323	>	logical, intent(in) :: do_pot
1324	>	integer, intent(in) :: atom1
1325	>	integer :: atid1
1326	>	real(kind=dp), dimension(9,nLocal) :: eFrame
1327	>	real(kind=dp), dimension(3,nLocal) :: t
1328	>	real(kind=dp) :: mu1, c1
1329	>	real(kind=dp) :: preVal, epot, mypot
1330	>	real(kind=dp) :: eix, eiy, eiz
1331	>
1332	>	! this is a local only array, so we use the local atom type id's:
1333	>	atid1 = atid(atom1)
1334	>
1335	>	if (.not.summationMethodChecked) then
1336	>	call checkSummationMethod()
1337	>	endif
1338	>
1339	>	if (summationMethod .eq. REACTION_FIELD) then
1340	>	if (ElectrostaticMap(atid1)%is_Dipole) then
1341	>	mu1 = getDipoleMoment(atid1)
1342	>
1343	>	preVal = pre22 * preRF2 * mu1*mu1
1344	>	mypot = mypot - 0.5d0*preVal
1345	>
1346	>	! The self-correction term adds into the reaction field vector
1347	>
1348	>	eix = preVal * eFrame(3,atom1)
1349	>	eiy = preVal * eFrame(6,atom1)
1350	>	eiz = preVal * eFrame(9,atom1)
1351	>
1352	>	! once again, this is self-self, so only the local arrays are needed
1353	>	! even for MPI jobs:
1354	>
1355	>	t(1,atom1)=t(1,atom1) - eFrame(6,atom1)*eiz + &
1356	>	eFrame(9,atom1)*eiy
1357	>	t(2,atom1)=t(2,atom1) - eFrame(9,atom1)*eix + &
1358	>	eFrame(3,atom1)*eiz
1359	>	t(3,atom1)=t(3,atom1) - eFrame(3,atom1)*eiy + &
1360	>	eFrame(6,atom1)*eix
1361	>
1362	>	endif
1363	>
1364	>	elseif (summationMethod .eq. UNDAMPED_WOLF) then
1365	>	if (ElectrostaticMap(atid1)%is_Charge) then
1366	>	c1 = getCharge(atid1)
1367	>
1368	>	mypot = mypot - (rcuti * 0.5_dp * c1 * c1)
1369	>	endif
1370	>
1371	>	elseif (summationMethod .eq. DAMPED_WOLF) then
1372	>	if (ElectrostaticMap(atid1)%is_Charge) then
1373	>	c1 = getCharge(atid1)
1374	>
1375	>	mypot = mypot - (constERFC * rcuti * 0.5_dp + &
1376	>	dampingAlpha*invRootPi) * c1 * c1
1377	>	endif
1378	>	endif
1379	>
1380	>	return
1381	>	end subroutine self_self
1382	>
1383	>	subroutine rf_self_excludes(atom1, atom2, sw, eFrame, d, rij, vpair, myPot, &
1384	>	f, t, do_pot)
1385	>	logical, intent(in) :: do_pot
1386	>	integer, intent(in) :: atom1
1387	>	integer, intent(in) :: atom2
1388	>	logical :: i_is_Charge, j_is_Charge
1389	>	logical :: i_is_Dipole, j_is_Dipole
1390	>	integer :: atid1
1391	>	integer :: atid2
1392	>	real(kind=dp), intent(in) :: rij
1393	>	real(kind=dp), intent(in) :: sw
1394	>	real(kind=dp), intent(in), dimension(3) :: d
1395	>	real(kind=dp), intent(inout) :: vpair
1396	>	real(kind=dp), dimension(9,nLocal) :: eFrame
1397	>	real(kind=dp), dimension(3,nLocal) :: f
1398	>	real(kind=dp), dimension(3,nLocal) :: t
1399	>	real (kind = dp), dimension(3) :: duduz_i
1400	>	real (kind = dp), dimension(3) :: duduz_j
1401	>	real (kind = dp), dimension(3) :: uz_i
1402	>	real (kind = dp), dimension(3) :: uz_j
1403	>	real(kind=dp) :: q_i, q_j, mu_i, mu_j
1404	>	real(kind=dp) :: xhat, yhat, zhat
1405	>	real(kind=dp) :: ct_i, ct_j
1406	>	real(kind=dp) :: ri2, ri3, riji, vterm
1407	>	real(kind=dp) :: pref, preVal, rfVal, myPot
1408	>	real(kind=dp) :: dudx, dudy, dudz, dudr
1409	>
1410	>	if (.not.summationMethodChecked) then
1411	>	call checkSummationMethod()
1412	>	endif
1413	>
1414	>	dudx = 0.0d0
1415	>	dudy = 0.0d0
1416	>	dudz = 0.0d0
1417	>
1418	>	riji = 1.0d0/rij
1419	>
1420	>	xhat = d(1) * riji
1421	>	yhat = d(2) * riji
1422	>	zhat = d(3) * riji
1423	>
1424	>	! this is a local only array, so we use the local atom type id's:
1425	>	atid1 = atid(atom1)
1426	>	atid2 = atid(atom2)
1427	>	i_is_Charge = ElectrostaticMap(atid1)%is_Charge
1428	>	j_is_Charge = ElectrostaticMap(atid2)%is_Charge
1429	>	i_is_Dipole = ElectrostaticMap(atid1)%is_Dipole
1430	>	j_is_Dipole = ElectrostaticMap(atid2)%is_Dipole
1431	>
1432	>	if (i_is_Charge.and.j_is_Charge) then
1433	>	q_i = ElectrostaticMap(atid1)%charge
1434	>	q_j = ElectrostaticMap(atid2)%charge
1435	>
1436	>	preVal = pre11 * q_i * q_j
1437	>	rfVal = preRF*rij*rij
1438	>	vterm = preVal * rfVal
1439	>
1440	>	myPot = myPot + sw*vterm
1441	>
1442	>	dudr  = sw*preVal * 2.0d0*rfVal*riji
1443	>
1444	>	dudx = dudx + dudr * xhat
1445	>	dudy = dudy + dudr * yhat
1446	>	dudz = dudz + dudr * zhat
1447	>
1448	>	elseif (i_is_Charge.and.j_is_Dipole) then
1449	>	q_i = ElectrostaticMap(atid1)%charge
1450	>	mu_j = ElectrostaticMap(atid2)%dipole_moment
1451	>	uz_j(1) = eFrame(3,atom2)
1452	>	uz_j(2) = eFrame(6,atom2)
1453	>	uz_j(3) = eFrame(9,atom2)
1454	>	ct_j = uz_j(1)*xhat + uz_j(2)*yhat + uz_j(3)*zhat
1455	>
1456	>	ri2 = riji * riji
1457	>	ri3 = ri2 * riji
1458	>
1459	>	pref = pre12 * q_i * mu_j
1460	>	vterm = - pref * ct_j * ( ri2 - preRF2*rij )
1461	>	myPot = myPot + sw*vterm
1462	>
1463	>	dudx = dudx - sw*pref*( ri3*(uz_j(1)-3.0d0*ct_j*xhat) &
1464	>	- preRF2*uz_j(1) )
1465	>	dudy = dudy - sw*pref*( ri3*(uz_j(2)-3.0d0*ct_j*yhat) &
1466	>	- preRF2*uz_j(2) )
1467	>	dudz = dudz - sw*pref*( ri3*(uz_j(3)-3.0d0*ct_j*zhat) &
1468	>	- preRF2*uz_j(3) )
1469	>
1470	>	duduz_j(1) = duduz_j(1) - sw * pref * xhat * ( ri2 - preRF2*rij )
1471	>	duduz_j(2) = duduz_j(2) - sw * pref * yhat * ( ri2 - preRF2*rij )
1472	>	duduz_j(3) = duduz_j(3) - sw * pref * zhat * ( ri2 - preRF2*rij )
1473	>
1474	>	elseif (i_is_Dipole.and.j_is_Charge) then
1475	>	mu_i = ElectrostaticMap(atid1)%dipole_moment
1476	>	q_j = ElectrostaticMap(atid2)%charge
1477	>	uz_i(1) = eFrame(3,atom1)
1478	>	uz_i(2) = eFrame(6,atom1)
1479	>	uz_i(3) = eFrame(9,atom1)
1480	>	ct_i = uz_i(1)*xhat + uz_i(2)*yhat + uz_i(3)*zhat
1481	>
1482	>	ri2 = riji * riji
1483	>	ri3 = ri2 * riji
1484	>
1485	>	pref = pre12 * q_j * mu_i
1486	>	vterm = pref * ct_i * ( ri2 - preRF2*rij )
1487	>	myPot = myPot + sw*vterm
1488	>
1489	>	dudx = dudx + sw*pref*( ri3*(uz_i(1)-3.0d0*ct_i*xhat) &
1490	>	- preRF2*uz_i(1) )
1491	>	dudy = dudy + sw*pref*( ri3*(uz_i(2)-3.0d0*ct_i*yhat) &
1492	>	- preRF2*uz_i(2) )
1493	>	dudz = dudz + sw*pref*( ri3*(uz_i(3)-3.0d0*ct_i*zhat) &
1494	>	- preRF2*uz_i(3) )
1495	>
1496	>	duduz_i(1) = duduz_i(1) + sw * pref * xhat * ( ri2 - preRF2*rij )
1497	>	duduz_i(2) = duduz_i(2) + sw * pref * yhat * ( ri2 - preRF2*rij )
1498	>	duduz_i(3) = duduz_i(3) + sw * pref * zhat * ( ri2 - preRF2*rij )
1499	>
1500	>	endif
1501	>
1502	>
1503	>	! accumulate the forces and torques resulting from the self term
1504	>	f(1,atom1) = f(1,atom1) + dudx
1505	>	f(2,atom1) = f(2,atom1) + dudy
1506	>	f(3,atom1) = f(3,atom1) + dudz
1507	>
1508	>	f(1,atom2) = f(1,atom2) - dudx
1509	>	f(2,atom2) = f(2,atom2) - dudy
1510	>	f(3,atom2) = f(3,atom2) - dudz
1511	>
1512	>	if (i_is_Dipole) then
1513	>	t(1,atom1)=t(1,atom1) - uz_i(2)*duduz_i(3) + uz_i(3)*duduz_i(2)
1514	>	t(2,atom1)=t(2,atom1) - uz_i(3)*duduz_i(1) + uz_i(1)*duduz_i(3)
1515	>	t(3,atom1)=t(3,atom1) - uz_i(1)*duduz_i(2) + uz_i(2)*duduz_i(1)
1516	>	elseif (j_is_Dipole) then
1517	>	t(1,atom2)=t(1,atom2) - uz_j(2)*duduz_j(3) + uz_j(3)*duduz_j(2)
1518	>	t(2,atom2)=t(2,atom2) - uz_j(3)*duduz_j(1) + uz_j(1)*duduz_j(3)
1519	>	t(3,atom2)=t(3,atom2) - uz_j(1)*duduz_j(2) + uz_j(2)*duduz_j(1)
1520	>	endif
1521	>
1522	>	return
1523	>	end subroutine rf_self_excludes
1524	>
1525		end module electrostatic_module

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