mdtools/libmdCode/calc_reaction_field.F90

module reaction_field
  use simulation
  use definitions
  use atype_module
  use vector_class
#ifdef IS_MPI
  use mpiSimulation
#endif
  implicit none

contains

  subroutine accumulate_rf(atom1, atom2, rij, u_l)

    integer, intent(in) :: atom1, atom2
    real (kind = dp), intent(in) :: rij
    real (kind = dp), dimension(3, getNlocal()) :: u_l    

    integer :: me1, me2
    real (kind = dp) :: rrf, rt, taper, mu1, mu2
    real (kind = dp), dimension(3) :: ul1
    real (kind = dp), dimension(3) :: ul2
    
    rrf = getRrf()
    
    if (rij.le.rrf) then
       
       rt = getRt()
       
       if (rij.lt.rt) then
          taper = 1.0d0
       else
          taper = (rrf + 2.0d0*rij - 3.0d0*rt)*(rrf-rij)**2/ ((rrf-rt)**3)
       endif
       
#ifdef IS_MPI
       me1 = atid_Row(atom1)
       ul1(1) = u_l_Row(1,atom1)
       ul1(2) = u_l_Row(2,atom1)
       ul1(3) = u_l_Row(3,atom1)
       
       me2 = atid_Col(atom2)
       ul2(1) = u_l_Col(1,atom2)
       ul2(2) = u_l_Col(2,atom2)
       ul2(3) = u_l_Col(3,atom2)
#else
       me1 = atid(atom1)
       ul1(1) = u_l(1,atom1)
       ul1(2) = u_l(2,atom1)
       ul1(3) = u_l(3,atom1)
       
       me2 = atid(atom2)
       ul2(1) = u_l(1,atom2)
       ul2(2) = u_l(2,atom2)
       ul2(3) = u_l(3,atom2)
#endif
       
       call getElementProperty(atypes, me1, "dipole_moment", mu1)
       call getElementProperty(atypes, me2, "dipole_moment", mu2)
       
       
#ifdef IS_MPI
       rf_Row(1,atom1) = rf_Row(1,atom1) + ul2(1)*mu2*taper
       rf_Row(2,atom1) = rf_Row(2,atom1) + ul2(2)*mu2*taper
       rf_Row(3,atom1) = rf_Row(3,atom1) + ul2(3)*mu2*taper
       
       rf_Col(1,atom2) = rf_Col(1,atom2) + ul1(1)*mu2*taper
       rf_Col(2,atom2) = rf_Col(2,atom2) + ul1(2)*mu2*taper
       rf_Col(3,atom2) = rf_Col(3,atom2) + ul1(3)*mu2*taper
#else
       rf(1,atom1) = rf(1,atom1) + ul2(1)*mu2*taper
       rf(2,atom1) = rf(2,atom1) + ul2(2)*mu2*taper
       rf(3,atom1) = rf(3,atom1) + ul2(3)*mu2*taper
       
       rf(1,atom2) = rf(1,atom2) + ul1(1)*mu2*taper
       rf(2,atom2) = rf(2,atom2) + ul1(2)*mu2*taper
       rf(3,atom2) = rf(3,atom2) + ul1(3)*mu2*taper     
#endif
       
    endif
    return  
  end subroutine accumulate_rf

  subroutine accumulate_self_rf(atom1, mu1, u_l)
    
    integer, intent(in) :: atom1
    real(kind=dp), intent(in) :: mu1
    real(kind=dp), dimension(3,getNlocal()) :: u_l
    
    !! should work for both MPI and non-MPI version since this is not pairwise.
    rf(1,atom1) = rf(1,atom1) + u_l(1,atom1)*mu1
    rf(2,atom1) = rf(2,atom1) + u_l(2,atom1)*mu1
    rf(3,atom1) = rf(3,atom1) + u_l(3,atom1)*mu1
        
    return
  end subroutine accumulate_self_rf
  
  subroutine reaction_field(a1, mu1, u_l, rfpot, t, do_pot)
            
    ! compute torques on dipoles:
    ! pre converts from mu in units of debye to kcal/mol
    
    rrf = getRrf()
    dielect = getDielect()
    rrfsq = rrf * rrf
    pre = 14.38362d0*2.0d0*(dielect-1.0d0)/((2.0d0*dielect+1.0d0)*rrfsq*rrf)
    
    ! The torque contribution is dipole cross reaction_field
    
    t(1,a1) = t(1,a1) + pre*mu1*(u_l(2,a1)*rf(3,a1) - u_l(3,a1)*rf(2,a1))
    t(2,a1) = t(2,a1) + pre*mu1*(u_l(3,a1)*rf(1,a1) - u_l(1,a1)*rf(3,a1))
    t(3,a1) = t(3,a1) + pre*mu1*(u_l(1,a1)*rf(2,a1) - u_l(2,a1)*rf(1,a1))
    
    ! the potential contribution is -1/2 dipole dot reaction_field
    
    if (do_pot) then
       rfpot = rfpot - 0.5d0 * pre * mu1 * &
            (rf(1,a1)*u_l(1,a1) + rf(2,a1)*u_l(2,a1) + rf(3,a1)*u_l(3,a1))
    endif
    
    return
  end subroutine reaction_field
  
  subroutine rf_correct_forces(atom1, atom2, d, rij, u_l, f, do_stress)
    
    integer, intent(in) :: atom1, atom2
    real(kind=dp), dimension(3), intent(in) :: d
    real(kind=dp), intent(in) :: rij
    real( kind = dp ), dimension(3,getNlocal()) :: u_l
    real( kind = dp ), dimension(3,getNlocal()) :: f
    logical, intent(in) :: do_stress
    
    real (kind = dp), dimension(3) :: ul1
    real (kind = dp), dimension(3) :: ul2
    real (kind = dp) :: dtdr, rrfsq, prerf
    real (kind = dp) :: dudx, dudy, dudz, u1dotu2
    
    rrf = getRrf()
    
    if (rij.le.rrf) then
       
       rrfsq = rrf * rrf
       dielect = getDielect()    
       prerf = 14.38362d0*2.0d0*(dielect-1.0d0)/((2.0d0*dielect+1.0d0)*rrfsq*rrf)
       rt = getRt()        
       
       if (rij.lt.rt) then
          dtdr = 0.0d0
       else
          dtdr = 6.0d0*(rij*rij - rij*rt - rij*rrf +rrf*rt)/((rrf-rt)**3)
       endif
       
#ifdef IS_MPI
       me1 = atid_Row(atom1)
       ul1(1) = u_l_Row(1,atom1)
       ul1(2) = u_l_Row(2,atom1)
       ul1(3) = u_l_Row(3,atom1)
       
       me2 = atid_Col(atom2)
       ul2(1) = u_l_Col(1,atom2)
       ul2(2) = u_l_Col(2,atom2)
       ul2(3) = u_l_Col(3,atom2)
#else
       me1 = atid(atom1)
       ul1(1) = u_l(1,atom1)
       ul1(2) = u_l(2,atom1)
       ul1(3) = u_l(3,atom1)
       
       me2 = atid(atom2)
       ul2(1) = u_l(1,atom2)
       ul2(2) = u_l(2,atom2)
       ul2(3) = u_l(3,atom2)
#endif
       
       call getElementProperty(atypes, me1, "dipole_moment", mu1)
       call getElementProperty(atypes, me2, "dipole_moment", mu2)
       
       u1dotu2 = ul1(1)*ul2(1) + ul1(2)*ul2(2) + ul1(3)*ul2(3)
       
       dudx = - prerf*mu1*mu2*u1dotu2*dtdr*d(1)/rij
       dudy = - prerf*mu1*mu2*u1dotu2*dtdr*d(2)/rij
       dudz = - prerf*mu1*mu2*u1dotu2*dtdr*d(3)/rij
       
#ifdef IS_MPI
       f_Row(1,atom1) = f_Row(1,atom1) + dudx
       f_Row(2,atom1) = f_Row(2,atom1) + dudy
       f_Row(3,atom1) = f_Row(3,atom1) + dudz
       
       f_Col(1,atom2) = f_Col(1,atom2) - dudx
       f_Col(2,atom2) = f_Col(2,atom2) - dudy
       f_Col(3,atom2) = f_Col(3,atom2) - dudz
#else
       f(1,atom1) = f(1,atom1) + dudx
       f(2,atom1) = f(2,atom1) + dudy
       f(3,atom1) = f(3,atom1) + dudz
       
       f(1,atom2) = f(1,atom2) - dudx
       f(2,atom2) = f(2,atom2) - dudy
       f(3,atom2) = f(3,atom2) - dudz
#endif
       
       if (do_stress) then          
          tau_Temp(1) = tau_Temp(1) + dudx * d(1)
          tau_Temp(2) = tau_Temp(2) + dudx * d(2)
          tau_Temp(3) = tau_Temp(3) + dudx * d(3)
          tau_Temp(4) = tau_Temp(4) + dudy * d(1)
          tau_Temp(5) = tau_Temp(5) + dudy * d(2)
          tau_Temp(6) = tau_Temp(6) + dudy * d(3)
          tau_Temp(7) = tau_Temp(7) + dudz * d(1)
          tau_Temp(8) = tau_Temp(8) + dudz * d(2)
          tau_Temp(9) = tau_Temp(9) + dudz * d(3)
          virial_Temp = virial_Temp + (tau_Temp(1) + tau_Temp(5) + tau_Temp(9))
       endif
       
    endif
    
    return
  end subroutine rf_correct_forces
end module reaction_field
Revision:	329
Committed:	Wed Mar 12 22:27:59 2003 UTC (21 years, 6 months ago) by gezelter
File size:	6637 byte(s)
Log Message:	Stick a fork in it. It's rare.
#	Content
1	module reaction_field
2	use simulation
3	use definitions
4	use atype_module
5	use vector_class
6	#ifdef IS_MPI
7	use mpiSimulation
8	#endif
9	implicit none
10
11	contains
12
13	subroutine accumulate_rf(atom1, atom2, rij, u_l)
14
15	integer, intent(in) :: atom1, atom2
16	real (kind = dp), intent(in) :: rij
17	real (kind = dp), dimension(3, getNlocal()) :: u_l
18
19	integer :: me1, me2
20	real (kind = dp) :: rrf, rt, taper, mu1, mu2
21	real (kind = dp), dimension(3) :: ul1
22	real (kind = dp), dimension(3) :: ul2
23
24	rrf = getRrf()
25
26	if (rij.le.rrf) then
27
28	rt = getRt()
29
30	if (rij.lt.rt) then
31	taper = 1.0d0
32	else
33	taper = (rrf + 2.0d0rij - 3.0d0rt)(rrf-rij)2/ ((rrf-rt)*3)
34	endif
35
36	#ifdef IS_MPI
37	me1 = atid_Row(atom1)
38	ul1(1) = u_l_Row(1,atom1)
39	ul1(2) = u_l_Row(2,atom1)
40	ul1(3) = u_l_Row(3,atom1)
41
42	me2 = atid_Col(atom2)
43	ul2(1) = u_l_Col(1,atom2)
44	ul2(2) = u_l_Col(2,atom2)
45	ul2(3) = u_l_Col(3,atom2)
46	#else
47	me1 = atid(atom1)
48	ul1(1) = u_l(1,atom1)
49	ul1(2) = u_l(2,atom1)
50	ul1(3) = u_l(3,atom1)
51
52	me2 = atid(atom2)
53	ul2(1) = u_l(1,atom2)
54	ul2(2) = u_l(2,atom2)
55	ul2(3) = u_l(3,atom2)
56	#endif
57
58	call getElementProperty(atypes, me1, "dipole_moment", mu1)
59	call getElementProperty(atypes, me2, "dipole_moment", mu2)
60
61
62	#ifdef IS_MPI
63	rf_Row(1,atom1) = rf_Row(1,atom1) + ul2(1)mu2taper
64	rf_Row(2,atom1) = rf_Row(2,atom1) + ul2(2)mu2taper
65	rf_Row(3,atom1) = rf_Row(3,atom1) + ul2(3)mu2taper
66
67	rf_Col(1,atom2) = rf_Col(1,atom2) + ul1(1)mu2taper
68	rf_Col(2,atom2) = rf_Col(2,atom2) + ul1(2)mu2taper
69	rf_Col(3,atom2) = rf_Col(3,atom2) + ul1(3)mu2taper
70	#else
71	rf(1,atom1) = rf(1,atom1) + ul2(1)mu2taper
72	rf(2,atom1) = rf(2,atom1) + ul2(2)mu2taper
73	rf(3,atom1) = rf(3,atom1) + ul2(3)mu2taper
74
75	rf(1,atom2) = rf(1,atom2) + ul1(1)mu2taper
76	rf(2,atom2) = rf(2,atom2) + ul1(2)mu2taper
77	rf(3,atom2) = rf(3,atom2) + ul1(3)mu2taper
78	#endif
79
80	endif
81	return
82	end subroutine accumulate_rf
83
84	subroutine accumulate_self_rf(atom1, mu1, u_l)
85
86	integer, intent(in) :: atom1
87	real(kind=dp), intent(in) :: mu1
88	real(kind=dp), dimension(3,getNlocal()) :: u_l
89
90	!! should work for both MPI and non-MPI version since this is not pairwise.
91	rf(1,atom1) = rf(1,atom1) + u_l(1,atom1)*mu1
92	rf(2,atom1) = rf(2,atom1) + u_l(2,atom1)*mu1
93	rf(3,atom1) = rf(3,atom1) + u_l(3,atom1)*mu1
94
95	return
96	end subroutine accumulate_self_rf
97
98	subroutine reaction_field(a1, mu1, u_l, rfpot, t, do_pot)
99
100	! compute torques on dipoles:
101	! pre converts from mu in units of debye to kcal/mol
102
103	rrf = getRrf()
104	dielect = getDielect()
105	rrfsq = rrf * rrf
106	pre = 14.38362d02.0d0(dielect-1.0d0)/((2.0d0dielect+1.0d0)rrfsq*rrf)
107
108	! The torque contribution is dipole cross reaction_field
109
110	t(1,a1) = t(1,a1) + premu1(u_l(2,a1)rf(3,a1) - u_l(3,a1)rf(2,a1))
111	t(2,a1) = t(2,a1) + premu1(u_l(3,a1)rf(1,a1) - u_l(1,a1)rf(3,a1))
112	t(3,a1) = t(3,a1) + premu1(u_l(1,a1)rf(2,a1) - u_l(2,a1)rf(1,a1))
113
114	! the potential contribution is -1/2 dipole dot reaction_field
115
116	if (do_pot) then
117	rfpot = rfpot - 0.5d0 * pre * mu1 * &
118	(rf(1,a1)u_l(1,a1) + rf(2,a1)u_l(2,a1) + rf(3,a1)*u_l(3,a1))
119	endif
120
121	return
122	end subroutine reaction_field
123
124	subroutine rf_correct_forces(atom1, atom2, d, rij, u_l, f, do_stress)
125
126	integer, intent(in) :: atom1, atom2
127	real(kind=dp), dimension(3), intent(in) :: d
128	real(kind=dp), intent(in) :: rij
129	real( kind = dp ), dimension(3,getNlocal()) :: u_l
130	real( kind = dp ), dimension(3,getNlocal()) :: f
131	logical, intent(in) :: do_stress
132
133	real (kind = dp), dimension(3) :: ul1
134	real (kind = dp), dimension(3) :: ul2
135	real (kind = dp) :: dtdr, rrfsq, prerf
136	real (kind = dp) :: dudx, dudy, dudz, u1dotu2
137
138	rrf = getRrf()
139
140	if (rij.le.rrf) then
141
142	rrfsq = rrf * rrf
143	dielect = getDielect()
144	prerf = 14.38362d02.0d0(dielect-1.0d0)/((2.0d0dielect+1.0d0)rrfsq*rrf)
145	rt = getRt()
146
147	if (rij.lt.rt) then
148	dtdr = 0.0d0
149	else
150	dtdr = 6.0d0(rijrij - rijrt - rijrrf +rrfrt)/((rrf-rt)*3)
151	endif
152
153	#ifdef IS_MPI
154	me1 = atid_Row(atom1)
155	ul1(1) = u_l_Row(1,atom1)
156	ul1(2) = u_l_Row(2,atom1)
157	ul1(3) = u_l_Row(3,atom1)
158
159	me2 = atid_Col(atom2)
160	ul2(1) = u_l_Col(1,atom2)
161	ul2(2) = u_l_Col(2,atom2)
162	ul2(3) = u_l_Col(3,atom2)
163	#else
164	me1 = atid(atom1)
165	ul1(1) = u_l(1,atom1)
166	ul1(2) = u_l(2,atom1)
167	ul1(3) = u_l(3,atom1)
168
169	me2 = atid(atom2)
170	ul2(1) = u_l(1,atom2)
171	ul2(2) = u_l(2,atom2)
172	ul2(3) = u_l(3,atom2)
173	#endif
174
175	call getElementProperty(atypes, me1, "dipole_moment", mu1)
176	call getElementProperty(atypes, me2, "dipole_moment", mu2)
177
178	u1dotu2 = ul1(1)ul2(1) + ul1(2)ul2(2) + ul1(3)*ul2(3)
179
180	dudx = - prerfmu1mu2u1dotu2dtdr*d(1)/rij
181	dudy = - prerfmu1mu2u1dotu2dtdr*d(2)/rij
182	dudz = - prerfmu1mu2u1dotu2dtdr*d(3)/rij
183
184	#ifdef IS_MPI
185	f_Row(1,atom1) = f_Row(1,atom1) + dudx
186	f_Row(2,atom1) = f_Row(2,atom1) + dudy
187	f_Row(3,atom1) = f_Row(3,atom1) + dudz
188
189	f_Col(1,atom2) = f_Col(1,atom2) - dudx
190	f_Col(2,atom2) = f_Col(2,atom2) - dudy
191	f_Col(3,atom2) = f_Col(3,atom2) - dudz
192	#else
193	f(1,atom1) = f(1,atom1) + dudx
194	f(2,atom1) = f(2,atom1) + dudy
195	f(3,atom1) = f(3,atom1) + dudz
196
197	f(1,atom2) = f(1,atom2) - dudx
198	f(2,atom2) = f(2,atom2) - dudy
199	f(3,atom2) = f(3,atom2) - dudz
200	#endif
201
202	if (do_stress) then
203	tau_Temp(1) = tau_Temp(1) + dudx * d(1)
204	tau_Temp(2) = tau_Temp(2) + dudx * d(2)
205	tau_Temp(3) = tau_Temp(3) + dudx * d(3)
206	tau_Temp(4) = tau_Temp(4) + dudy * d(1)
207	tau_Temp(5) = tau_Temp(5) + dudy * d(2)
208	tau_Temp(6) = tau_Temp(6) + dudy * d(3)
209	tau_Temp(7) = tau_Temp(7) + dudz * d(1)
210	tau_Temp(8) = tau_Temp(8) + dudz * d(2)
211	tau_Temp(9) = tau_Temp(9) + dudz * d(3)
212	virial_Temp = virial_Temp + (tau_Temp(1) + tau_Temp(5) + tau_Temp(9))
213	endif
214
215	endif
216
217	return
218	end subroutine rf_correct_forces
219	end module reaction_field