c c c ################################################### c ## COPYRIGHT (C) 1998 by Jay William Ponder ## c ## All Rights Reserved ## c ################################################### c c ################################################################ c ## ## c ## subroutine emm3hb2 -- atomwise MM3 vdw & hbond Hessian ## c ## ## c ################################################################ c c c "emm3hb2" calculates the MM3 exp-6 van der Waals and directional c charge transfer hydrogen bonding second derivatives for a single c atom at a time c c note this version only partially incorporates the directional c hydrogen bonding term into the Hessian calculation c c literature references: c c J.-H. Lii and N. L. Allinger, "Directional Hydrogen Bonding in c the MM3 Force Field. I", Journal of Physical Organic Chemistry, c 7, 591-609 (1994) c c J.-H. Lii and N. L. Allinger, "Directional Hydrogen Bonding in c the MM3 Force Field. II", Journal of Computational Chemistry, c 19, 1001-1016 (1998) c c subroutine emm3hb2 (iatom) use atmlst use atomid use atoms use bndstr use bound use cell use chgpot use couple use group use hessn use shunt use vdw use vdwpot implicit none integer i,j,k integer ii,it,iv integer kk,kt,kv integer iatom,jcell integer ia,ib,ic integer nlist,list(5) integer, allocatable :: iv14(:) real*8 e,de,d2e,fgrp real*8 eps,rv,rdn real*8 p,p2,p6,p12 real*8 xi,yi,zi real*8 xr,yr,zr real*8 redi,rediv real*8 redk,redkv real*8 redi2,rediv2,rediiv real*8 redik,redivk real*8 redikv,redivkv real*8 rik,rik2,rik3 real*8 rik4,rik5 real*8 taper,dtaper,d2taper real*8 d2edx,d2edy,d2edz real*8 expcut,expcut2 real*8 expterm,expmin2 real*8 expmerge real*8 rvterm,rvterm2 real*8 dot,cosine,sine real*8 fterm,fcbuck real*8 ideal,ratio real*8 xia,yia,zia real*8 xib,yib,zib real*8 xic,yic,zic real*8 xab,yab,zab real*8 xcb,ycb,zcb real*8 rab2,rab,rcb2 real*8 xp,yp,zp,rp real*8 term(3,3) real*8, allocatable :: vscale(:) logical proceed character*6 mode c c c perform dynamic allocation of some local arrays c allocate (iv14(n)) allocate (vscale(n)) c c set arrays needed to scale connected atom interactions c do i = 1, n iv14(i) = 0 vscale(i) = 1.0d0 end do c c set the coefficients for the switching function c mode = 'VDW' call switch (mode) c c special cutoffs for very short and very long range terms c expmin2 = 0.01d0 expcut = 2.0d0 expcut2 = expcut * expcut expmerge = (abuck*exp(-bbuck/expcut) - cbuck*(expcut**6)) & / (expcut**12) c c check to see if the atom of interest is a vdw site c nlist = 0 do k = 1, nvdw if (ivdw(k) .eq. iatom) then nlist = nlist + 1 list(nlist) = iatom goto 10 end if end do return 10 continue c c apply any reduction factor to the atomic coordinates c do k = 1, nvdw i = ivdw(k) iv = ired(i) rdn = kred(i) xred(i) = rdn*(x(i)-x(iv)) + x(iv) yred(i) = rdn*(y(i)-y(iv)) + y(iv) zred(i) = rdn*(z(i)-z(iv)) + z(iv) end do c c determine the atoms involved via reduction factors c nlist = 1 list(nlist) = iatom do k = 1, n12(iatom) i = i12(k,iatom) if (ired(i) .eq. iatom) then nlist = nlist + 1 list(nlist) = i end if end do c c find van der Waals Hessian elements for involved atoms c do ii = 1, nlist i = list(ii) it = jvdw(i) iv = ired(i) redi = kred(i) if (i .ne. iv) then rediv = 1.0d0 - redi redi2 = redi * redi rediv2 = rediv * rediv rediiv = redi * rediv end if xi = xred(i) yi = yred(i) zi = zred(i) c c set exclusion coefficients for connected atoms c do j = 1, n12(i) vscale(i12(j,i)) = v2scale end do do j = 1, n13(i) vscale(i13(j,i)) = v3scale end do do j = 1, n14(i) vscale(i14(j,i)) = v4scale iv14(i14(j,i)) = i end do do j = 1, n15(i) vscale(i15(j,i)) = v5scale end do c c decide whether to compute the current interaction c do kk = 1, nvdw k = ivdw(kk) kt = jvdw(k) kv = ired(k) proceed = .true. if (use_group) call groups (proceed,fgrp,i,k,0,0,0,0) if (proceed) proceed = (k .ne. i) c c compute the Hessian elements for this interaction c if (proceed) then xr = xi - xred(k) yr = yi - yred(k) zr = zi - zred(k) call image (xr,yr,zr) rik2 = xr*xr + yr*yr + zr*zr c c check for an interaction distance less than the cutoff c if (rik2 .le. off2) then fterm = 1.0d0 rv = radmin(kt,it) eps = epsilon(kt,it) if (iv14(k) .eq. i) then rv = radmin4(kt,it) eps = epsilon4(kt,it) else if (radhbnd(kt,it) .ne. 0.0d0) then rv = radhbnd(kt,it) eps = epshbnd(kt,it) / dielec if (atomic(i) .eq. 1) then ia = i ib = i12(1,i) ic = k else ia = k ib = i12(1,k) ic = i end if xia = x(ia) yia = y(ia) zia = z(ia) xib = x(ib) yib = y(ib) zib = z(ib) xic = x(ic) yic = y(ic) zic = z(ic) xab = xia - xib yab = yia - yib zab = zia - zib xcb = xic - xib ycb = yic - yib zcb = zic - zib call image (xcb,ycb,zcb) xp = ycb*zab - zcb*yab yp = zcb*xab - xcb*zab zp = xcb*yab - ycb*xab rp = sqrt(xp*xp + yp*yp + zp*zp) rab2 = max(xab*xab+yab*yab+zab*zab,0.0001d0) rcb2 = max(xcb*xcb+ycb*ycb+zcb*zcb,0.0001d0) dot = xab*xcb + yab*ycb + zab*zcb cosine = dot / sqrt(rab2*rcb2) sine = sqrt(abs(1.0d0-cosine**2)) rab = sqrt(rab2) ideal = bl(bndlist(1,ia)) ratio = rab / ideal fterm = cosine * ratio end if eps = eps * vscale(k) p2 = (rv*rv) / rik2 p6 = p2 * p2 * p2 rik = sqrt(rik2) if (p2 .le. expmin2) then e = 0.0d0 de = 0.0d0 d2e = 0.0d0 else if (p2 .le. expcut2) then p = sqrt(p2) rvterm = -bbuck / rv rvterm2 = rvterm * rvterm expterm = abuck * exp(-bbuck/p) fcbuck = fterm * cbuck * p6 e = eps * (expterm - fcbuck) de = eps * (rvterm*expterm+6.0d0*fcbuck/rik) d2e = eps * (rvterm2*expterm-42.0d0*fcbuck/rik2) else p12 = p6 * p6 e = expmerge * eps * p12 de = -12.0d0 * e / rik d2e = 156.0d0 * e / rik2 end if c c use energy switching if near the cutoff distance c if (rik2 .gt. cut2) then rik3 = rik2 * rik rik4 = rik2 * rik2 rik5 = rik2 * rik3 taper = c5*rik5 + c4*rik4 + c3*rik3 & + c2*rik2 + c1*rik + c0 dtaper = 5.0d0*c5*rik4 + 4.0d0*c4*rik3 & + 3.0d0*c3*rik2 + 2.0d0*c2*rik + c1 d2taper = 20.0d0*c5*rik3 + 12.0d0*c4*rik2 & + 6.0d0*c3*rik + 2.0d0*c2 d2e = e*d2taper + 2.0d0*de*dtaper + d2e*taper de = e*dtaper + de*taper end if c c scale the interaction based on its group membership c if (use_group) then de = de * fgrp d2e = d2e * fgrp end if c c get chain rule terms for van der Waals Hessian elements c de = de / rik d2e = (d2e-de) / rik2 d2edx = d2e * xr d2edy = d2e * yr d2edz = d2e * zr term(1,1) = d2edx*xr + de term(1,2) = d2edx*yr term(1,3) = d2edx*zr term(2,1) = term(1,2) term(2,2) = d2edy*yr + de term(2,3) = d2edy*zr term(3,1) = term(1,3) term(3,2) = term(2,3) term(3,3) = d2edz*zr + de c c increment diagonal and off-diagonal Hessian elements c if (i .eq. iatom) then if (i.eq.iv .and. k.eq.kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j) hessy(j,i) = hessy(j,i) + term(2,j) hessz(j,i) = hessz(j,i) + term(3,j) hessx(j,k) = hessx(j,k) - term(1,j) hessy(j,k) = hessy(j,k) - term(2,j) hessz(j,k) = hessz(j,k) - term(3,j) end do else if (k .eq. kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*redi2 hessy(j,i) = hessy(j,i) + term(2,j)*redi2 hessz(j,i) = hessz(j,i) + term(3,j)*redi2 hessx(j,k) = hessx(j,k) - term(1,j)*redi hessy(j,k) = hessy(j,k) - term(2,j)*redi hessz(j,k) = hessz(j,k) - term(3,j)*redi hessx(j,iv) = hessx(j,iv) + term(1,j)*rediiv hessy(j,iv) = hessy(j,iv) + term(2,j)*rediiv hessz(j,iv) = hessz(j,iv) + term(3,j)*rediiv end do else if (i .eq. iv) then redk = kred(k) redkv = 1.0d0 - redk do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j) hessy(j,i) = hessy(j,i) + term(2,j) hessz(j,i) = hessz(j,i) + term(3,j) hessx(j,k) = hessx(j,k) - term(1,j)*redk hessy(j,k) = hessy(j,k) - term(2,j)*redk hessz(j,k) = hessz(j,k) - term(3,j)*redk hessx(j,kv) = hessx(j,kv) - term(1,j)*redkv hessy(j,kv) = hessy(j,kv) - term(2,j)*redkv hessz(j,kv) = hessz(j,kv) - term(3,j)*redkv end do else redk = kred(k) redkv = 1.0d0 - redk redik = redi * redk redikv = redi * redkv do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*redi2 hessy(j,i) = hessy(j,i) + term(2,j)*redi2 hessz(j,i) = hessz(j,i) + term(3,j)*redi2 hessx(j,k) = hessx(j,k) - term(1,j)*redik hessy(j,k) = hessy(j,k) - term(2,j)*redik hessz(j,k) = hessz(j,k) - term(3,j)*redik hessx(j,iv) = hessx(j,iv) + term(1,j)*rediiv hessy(j,iv) = hessy(j,iv) + term(2,j)*rediiv hessz(j,iv) = hessz(j,iv) + term(3,j)*rediiv hessx(j,kv) = hessx(j,kv) - term(1,j)*redikv hessy(j,kv) = hessy(j,kv) - term(2,j)*redikv hessz(j,kv) = hessz(j,kv) - term(3,j)*redikv end do end if else if (iv .eq. iatom) then if (k .eq. kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*rediiv hessy(j,i) = hessy(j,i) + term(2,j)*rediiv hessz(j,i) = hessz(j,i) + term(3,j)*rediiv hessx(j,k) = hessx(j,k) - term(1,j)*rediv hessy(j,k) = hessy(j,k) - term(2,j)*rediv hessz(j,k) = hessz(j,k) - term(3,j)*rediv hessx(j,iv) = hessx(j,iv) + term(1,j)*rediv2 hessy(j,iv) = hessy(j,iv) + term(2,j)*rediv2 hessz(j,iv) = hessz(j,iv) + term(3,j)*rediv2 end do else redk = kred(k) redkv = 1.0d0 - redk redivk = rediv * redk redivkv = rediv * redkv do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*rediiv hessy(j,i) = hessy(j,i) + term(2,j)*rediiv hessz(j,i) = hessz(j,i) + term(3,j)*rediiv hessx(j,k) = hessx(j,k) - term(1,j)*redivk hessy(j,k) = hessy(j,k) - term(2,j)*redivk hessz(j,k) = hessz(j,k) - term(3,j)*redivk hessx(j,iv) = hessx(j,iv) + term(1,j)*rediv2 hessy(j,iv) = hessy(j,iv) + term(2,j)*rediv2 hessz(j,iv) = hessz(j,iv) + term(3,j)*rediv2 hessx(j,kv) = hessx(j,kv) - term(1,j)*redivkv hessy(j,kv) = hessy(j,kv) - term(2,j)*redivkv hessz(j,kv) = hessz(j,kv) - term(3,j)*redivkv end do end if end if end if end if end do c c reset exclusion coefficients for connected atoms c do j = 1, n12(i) vscale(i12(j,i)) = 1.0d0 end do do j = 1, n13(i) vscale(i13(j,i)) = 1.0d0 end do do j = 1, n14(i) vscale(i14(j,i)) = 1.0d0 end do do j = 1, n15(i) vscale(i15(j,i)) = 1.0d0 end do end do c c for periodic boundary conditions with large cutoffs c neighbors must be found by the replicates method c if (.not. use_replica) return c c calculate interaction energy with other unit cells c do ii = 1, nlist i = list(ii) it = jvdw(i) iv = ired(i) redi = kred(i) if (i .ne. iv) then rediv = 1.0d0 - redi redi2 = redi * redi rediv2 = rediv * rediv rediiv = redi * rediv end if xi = xred(i) yi = yred(i) zi = zred(i) c c set exclusion coefficients for connected atoms c do j = 1, n12(i) vscale(i12(j,i)) = v2scale end do do j = 1, n13(i) vscale(i13(j,i)) = v3scale end do do j = 1, n14(i) vscale(i14(j,i)) = v4scale iv14(i14(j,i)) = i end do do j = 1, n15(i) vscale(i15(j,i)) = v5scale end do c c decide whether to compute the current interaction c do kk = 1, nvdw k = ivdw(kk) kt = jvdw(k) kv = ired(k) proceed = .true. if (use_group) call groups (proceed,fgrp,i,k,0,0,0,0) c c compute the Hessian elements for this interaction c if (proceed) then do jcell = 2, ncell xr = xi - xred(k) yr = yi - yred(k) zr = zi - zred(k) call imager (xr,yr,zr,jcell) rik2 = xr*xr + yr*yr + zr*zr c c check for an interaction distance less than the cutoff c if (rik2 .le. off2) then fterm = 1.0d0 rv = radmin(kt,it) eps = epsilon(kt,it) if (radhbnd(kt,it) .ne. 0.0d0) then rv = radhbnd(kt,it) eps = epshbnd(kt,it) / dielec if (atomic(i) .eq. 1) then ia = i ib = i12(1,i) ic = k else ia = k ib = i12(1,k) ic = i end if xia = x(ia) yia = y(ia) zia = z(ia) xib = x(ib) yib = y(ib) zib = z(ib) xic = x(ic) yic = y(ic) zic = z(ic) xab = xia - xib yab = yia - yib zab = zia - zib xcb = xic - xib ycb = yic - yib zcb = zic - zib call imager (xcb,ycb,zcb,jcell) xp = ycb*zab - zcb*yab yp = zcb*xab - xcb*zab zp = xcb*yab - ycb*xab rp = sqrt(xp*xp + yp*yp + zp*zp) rab2 = max(xab*xab+yab*yab+zab*zab,0.0001d0) rcb2 = max(xcb*xcb+ycb*ycb+zcb*zcb,0.0001d0) dot = xab*xcb + yab*ycb + zab*zcb cosine = dot / sqrt(rab2*rcb2) sine = sqrt(abs(1.0d0-cosine**2)) rab = sqrt(rab2) ideal = bl(bndlist(1,ia)) ratio = rab / ideal fterm = cosine * ratio end if if (use_polymer) then if (rik2 .le. polycut2) then if (iv14(k) .eq. i) then fterm = 1.0d0 rv = radmin4(kt,it) eps = epsilon4(kt,it) end if eps = eps * vscale(k) end if end if p2 = (rv*rv) / rik2 p6 = p2 * p2 * p2 rik = sqrt(rik2) if (p2 .le. expmin2) then e = 0.0d0 de = 0.0d0 d2e = 0.0d0 else if (p2 .le. expcut2) then p = sqrt(p2) rvterm = -bbuck / rv rvterm2 = rvterm * rvterm expterm = abuck * exp(-bbuck/p) fcbuck = fterm * cbuck * p6 e = eps * (expterm - fcbuck) de = eps * (rvterm*expterm+6.0d0*fcbuck/rik) d2e = eps * (rvterm2*expterm-42.0d0*fcbuck/rik2) else p12 = p6 * p6 e = expmerge * eps * p12 de = -12.0d0 * e / rik d2e = 156.0d0 * e / rik2 end if c c use energy switching if near the cutoff distance c if (rik2 .gt. cut2) then rik3 = rik2 * rik rik4 = rik2 * rik2 rik5 = rik2 * rik3 taper = c5*rik5 + c4*rik4 + c3*rik3 & + c2*rik2 + c1*rik + c0 dtaper = 5.0d0*c5*rik4 + 4.0d0*c4*rik3 & + 3.0d0*c3*rik2 + 2.0d0*c2*rik + c1 d2taper = 20.0d0*c5*rik3 + 12.0d0*c4*rik2 & + 6.0d0*c3*rik + 2.0d0*c2 d2e = e*d2taper + 2.0d0*de*dtaper + d2e*taper de = e*dtaper + de*taper end if c c scale the interaction based on its group membership c if (use_group) then de = de * fgrp d2e = d2e * fgrp end if c c get chain rule terms for van der Waals Hessian elements c de = de / rik d2e = (d2e-de) / rik2 d2edx = d2e * xr d2edy = d2e * yr d2edz = d2e * zr term(1,1) = d2edx*xr + de term(1,2) = d2edx*yr term(1,3) = d2edx*zr term(2,1) = term(1,2) term(2,2) = d2edy*yr + de term(2,3) = d2edy*zr term(3,1) = term(1,3) term(3,2) = term(2,3) term(3,3) = d2edz*zr + de c c increment diagonal and off-diagonal Hessian elements c if (i .eq. iatom) then if (i.eq.iv .and. k.eq.kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j) hessy(j,i) = hessy(j,i) + term(2,j) hessz(j,i) = hessz(j,i) + term(3,j) hessx(j,k) = hessx(j,k) - term(1,j) hessy(j,k) = hessy(j,k) - term(2,j) hessz(j,k) = hessz(j,k) - term(3,j) end do else if (k .eq. kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*redi2 hessy(j,i) = hessy(j,i) + term(2,j)*redi2 hessz(j,i) = hessz(j,i) + term(3,j)*redi2 hessx(j,k) = hessx(j,k) - term(1,j)*redi hessy(j,k) = hessy(j,k) - term(2,j)*redi hessz(j,k) = hessz(j,k) - term(3,j)*redi hessx(j,iv) = hessx(j,iv) & + term(1,j)*rediiv hessy(j,iv) = hessy(j,iv) & + term(2,j)*rediiv hessz(j,iv) = hessz(j,iv) & + term(3,j)*rediiv end do else if (i .eq. iv) then redk = kred(k) redkv = 1.0d0 - redk do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j) hessy(j,i) = hessy(j,i) + term(2,j) hessz(j,i) = hessz(j,i) + term(3,j) hessx(j,k) = hessx(j,k) - term(1,j)*redk hessy(j,k) = hessy(j,k) - term(2,j)*redk hessz(j,k) = hessz(j,k) - term(3,j)*redk hessx(j,kv) = hessx(j,kv) & - term(1,j)*redkv hessy(j,kv) = hessy(j,kv) & - term(2,j)*redkv hessz(j,kv) = hessz(j,kv) & - term(3,j)*redkv end do else redk = kred(k) redkv = 1.0d0 - redk redik = redi * redk redikv = redi * redkv do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*redi2 hessy(j,i) = hessy(j,i) + term(2,j)*redi2 hessz(j,i) = hessz(j,i) + term(3,j)*redi2 hessx(j,k) = hessx(j,k) - term(1,j)*redik hessy(j,k) = hessy(j,k) - term(2,j)*redik hessz(j,k) = hessz(j,k) - term(3,j)*redik hessx(j,iv) = hessx(j,iv) & + term(1,j)*rediiv hessy(j,iv) = hessy(j,iv) & + term(2,j)*rediiv hessz(j,iv) = hessz(j,iv) & + term(3,j)*rediiv hessx(j,kv) = hessx(j,kv) & - term(1,j)*redikv hessy(j,kv) = hessy(j,kv) & - term(2,j)*redikv hessz(j,kv) = hessz(j,kv) & - term(3,j)*redikv end do end if else if (iv .eq. iatom) then if (k .eq. kv) then do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*rediiv hessy(j,i) = hessy(j,i) + term(2,j)*rediiv hessz(j,i) = hessz(j,i) + term(3,j)*rediiv hessx(j,k) = hessx(j,k) - term(1,j)*rediv hessy(j,k) = hessy(j,k) - term(2,j)*rediv hessz(j,k) = hessz(j,k) - term(3,j)*rediv hessx(j,iv) = hessx(j,iv) & + term(1,j)*rediv2 hessy(j,iv) = hessy(j,iv) & + term(2,j)*rediv2 hessz(j,iv) = hessz(j,iv) & + term(3,j)*rediv2 end do else redk = kred(k) redkv = 1.0d0 - redk redivk = rediv * redk redivkv = rediv * redkv do j = 1, 3 hessx(j,i) = hessx(j,i) + term(1,j)*rediiv hessy(j,i) = hessy(j,i) + term(2,j)*rediiv hessz(j,i) = hessz(j,i) + term(3,j)*rediiv hessx(j,k) = hessx(j,k) - term(1,j)*redivk hessy(j,k) = hessy(j,k) - term(2,j)*redivk hessz(j,k) = hessz(j,k) - term(3,j)*redivk hessx(j,iv) = hessx(j,iv) & + term(1,j)*rediv2 hessy(j,iv) = hessy(j,iv) & + term(2,j)*rediv2 hessz(j,iv) = hessz(j,iv) & + term(3,j)*rediv2 hessx(j,kv) = hessx(j,kv) & - term(1,j)*redivkv hessy(j,kv) = hessy(j,kv) & - term(2,j)*redivkv hessz(j,kv) = hessz(j,kv) & - term(3,j)*redivkv end do end if end if end if end do end if end do c c reset exclusion coefficients for connected atoms c do j = 1, n12(i) vscale(i12(j,i)) = 1.0d0 end do do j = 1, n13(i) vscale(i13(j,i)) = 1.0d0 end do do j = 1, n14(i) vscale(i14(j,i)) = 1.0d0 end do do j = 1, n15(i) vscale(i15(j,i)) = 1.0d0 end do end do c c perform deallocation of some local arrays c deallocate (iv14) deallocate (vscale) return end