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gezelter |
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subroutine accumulate_rf(atom1, atom2, rij) |
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include 'sizes.inc' |
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include 'simulation.inc' |
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integer atom1, atom2 |
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double precision taper, rij |
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if (rij.le.rrf) then |
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if (rij.lt.rt) then |
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taper = 1.0d0 |
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else |
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taper = (rrf + 2.0d0*rij - 3.0d0*rt)*(rrf-rij)**2/ ((rrf-rt)**3) |
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endif |
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rflx(atom1) = rflx(atom1) + ulx(atom2)*mu(atom2)*taper |
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rfly(atom1) = rfly(atom1) + uly(atom2)*mu(atom2)*taper |
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rflz(atom1) = rflz(atom1) + ulz(atom2)*mu(atom2)*taper |
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rflx(atom2) = rflx(atom2) + ulx(atom1)*mu(atom1)*taper |
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rfly(atom2) = rfly(atom2) + uly(atom1)*mu(atom1)*taper |
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rflz(atom2) = rflz(atom2) + ulz(atom1)*mu(atom1)*taper |
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endif |
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return |
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end subroutine accumulate_rf |
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subroutine accumulate_self_rf() |
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include 'sizes.inc' |
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include 'simulation.inc' |
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integer i, ia, a1, atype1 |
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logical is_dipole_atype |
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external is_dipole_atype |
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do i = 1, nmol |
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do ia = 1, na(i) |
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a1 = atom_index(i,ia) |
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atype1 = atype(a1) |
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if (is_dipole_atype(atype1)) then |
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rflx(a1) = rflx(a1) + ulx(a1)*mu(a1) |
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rfly(a1) = rfly(a1) + uly(a1)*mu(a1) |
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rflz(a1) = rflz(a1) + ulz(a1)*mu(a1) |
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endif |
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enddo |
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enddo |
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return |
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end subroutine accumulate_self_rf |
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subroutine reaction_field(pot) |
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include 'sizes.inc' |
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include 'simulation.inc' |
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double precision rrfsq, pre |
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integer i, ia, a1, atype1 |
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logical is_dipole_atype |
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external is_dipole_atype |
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! do single loop to compute torques on dipoles: |
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! pre converts from mu in units of debye to kcal/mol |
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rrfsq = rrf * rrf |
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pre = 14.38362d0*2.0d0*(dielect-1.0d0)/((2.0d0*dielect+1.0d0)*rrfsq*rrf) |
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do i = 1, nmol |
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do ia = 1, na(i) |
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a1 = atom_index(i,ia) |
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atype1 = atype(a1) |
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if (is_dipole_atype(atype1)) then |
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! The torque contribution is dipole cross reaction_field |
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tlx(a1) = tlx(a1) + pre*mu(a1)*(uly(a1)*rflz(a1) - ulz(a1)*rfly(a1)) |
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tly(a1) = tly(a1) + pre*mu(a1)*(ulz(a1)*rflx(a1) - ulx(a1)*rflz(a1)) |
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tlz(a1) = tlz(a1) + pre*mu(a1)*(ulx(a1)*rfly(a1) - uly(a1)*rflx(a1)) |
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! the potential contribution is -1/2 dipole dot reaction_field |
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pot = pot - 0.5d0 * pre * mu(a1) * & |
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(rflx(a1)*ulx(a1) + rfly(a1)*uly(a1) + rflz(a1)*ulz(a1)) |
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endif |
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enddo |
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enddo |
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end subroutine reaction_field |
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subroutine rf_correct_forces(atom1, atom2, dx, dy, dz, rij) |
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include 'sizes.inc' |
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include 'simulation.inc' |
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integer atom1, atom2 |
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double precision dtdr, rrfsq, prerf, rij |
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double precision dudx, dudy, dudz, u1dotu2, dx, dy, dz |
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rrfsq = rrf * rrf |
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prerf = 14.38362d0*2.0d0*(dielect-1.0d0)/((2.0d0*dielect+1.0d0)*rrfsq*rrf) |
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if (rij.le.rrf) then |
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! cubic taper |
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if (rij.lt.rt) then |
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dtdr = 0.0d0 |
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else |
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dtdr = 6.0d0*(rij*rij - rij*rt - rij*rrf +rrf*rt)/((rrf-rt)**3) |
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endif |
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u1dotu2 = ulx(atom1)*ulx(atom2) + uly(atom1)*uly(atom2) + & |
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ulz(atom1)*ulz(atom2) |
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dudx = - prerf*mu(atom1)*mu(atom2)*u1dotu2*dtdr*dx/rij |
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dudy = - prerf*mu(atom1)*mu(atom2)*u1dotu2*dtdr*dy/rij |
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dudz = - prerf*mu(atom1)*mu(atom2)*u1dotu2*dtdr*dz/rij |
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flx(atom1) = flx(atom1) + dudx |
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fly(atom1) = fly(atom1) + dudy |
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flz(atom1) = flz(atom1) + dudz |
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flx(atom2) = flx(atom2) - dudx |
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fly(atom2) = fly(atom2) - dudy |
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flz(atom2) = flz(atom2) - dudz |
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! add contribution to the virial as well |
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virial = virial + ( dx*dudx + dy*dudy + dz*dudz ) |
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endif |
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return |
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end subroutine rf_correct_forces |