add CC-B88

src/eDFT/CC_B88_gga_exchange_energy.f90

@@ -0,0 +1,100 @@
+subroutine CC_B88_gga_exchange_energy(nEns,wEns,nCC,aCC,nGrid,weight,&
+                                     rho,drho,Cx_choice,Ex)
+
+! Compute the unrestricted version of the curvature-corrected exchange functional
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  integer,intent(in)            :: nEns
+  double precision,intent(in)   :: wEns(nEns)
+  integer,intent(in)            :: nCC
+  double precision,intent(in)   :: aCC(nCC,nEns-1)
+  integer,intent(in)            :: nGrid
+  double precision,intent(in)   :: weight(nGrid)
+  double precision,intent(in)   :: rho(nGrid)
+  double precision,intent(in)   :: drho(3,nGrid)
+  integer,intent(in)            :: Cx_choice
+
+! Local variables
+
+  integer                       :: iG
+  double precision              :: b
+  double precision              :: r,g,x
+
+  double precision              :: a1,b1,c1,d1,w1
+  double precision              :: a2,b2,c2,d2,w2
+  double precision              :: Fx1,Fx2,Cx
+
+! Output variables
+
+  double precision              :: Ex
+
+! Coefficients for B88 GGA exchange functional
+
+  b = 0.0042d0
+
+! Defining enhancements factor for weight-dependent functionals
+
+! Parameters for first state
+
+     a1 = aCC(1,1)
+     b1 = aCC(2,1)
+     c1 = aCC(3,1)
+     d1 = aCC(4,1)
+
+! Parameters for second state
+
+     a2 = aCC(1,2)
+     b2 = aCC(2,2)
+     c2 = aCC(3,2)
+     d2 = aCC(4,2)
+
+
+     w1 = wEns(2)
+     Fx1 = 1d0 + a1*w1 + b1*w1**2 + c1*w1**3 + d1*w1**4
+
+     w2 = wEns(3)
+     Fx2 = 1d0 + a2*w2 + b2*w2**2 + c2*w2**3 + d2*w2**4
+
+
+  select case (Cx_choice)
+
+    case(1)
+      Cx = Fx1
+
+    case(2)
+      Cx = Fx2
+
+    case(3)
+      Cx = Fx2*Fx1
+
+    case default
+      Cx = 1.d0
+
+  end select
+
+
+! Compute GIC-GGA exchange energy
+
+  Ex = 0d0
+
+  do iG=1,nGrid
+
+    r = max(0d0,rho(iG))
+
+    if(r > threshold) then
+      g = drho(1,iG)**2 + drho(2,iG)**2 + drho(3,iG)**2
+      x = sqrt(g)/r**(4d0/3d0)
+
+      Ex = Ex + weight(iG)*r**(4d0/3d0)*(CxLSDA - b*x**2/(1d0 + 6d0*b*x*asinh(x)))
+
+    end if
+
+  end do
+
+  Ex = Cx*Ex
+
+end subroutine CC_B88_gga_exchange_energy

src/eDFT/CC_B88_gga_exchange_potential.f90

@@ -0,0 +1,125 @@
+subroutine CC_B88_gga_exchange_potential(nEns,wEns,nCC,aCC,nGrid,weight,nBas,&
+                                         AO,dAO,rho,drho,Cx_choice,doNcentered,Fx)
+
+! Compute the unrestricted version of the curvature-corrected exchange potential
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  integer,intent(in)            :: nEns
+  double precision,intent(in)   :: wEns(nEns)
+  integer,intent(in)            :: nCC
+  double precision,intent(in)   :: aCC(nCC,nEns-1)
+  integer,intent(in)            :: nGrid
+  double precision,intent(in)   :: weight(nGrid)
+  integer,intent(in)            :: nBas
+  double precision,intent(in)   :: AO(nBas,nGrid)
+  double precision,intent(in)   :: dAO(3,nBas,nGrid)
+  double precision,intent(in)   :: rho(nGrid)
+  double precision,intent(in)   :: drho(3,nGrid)
+  integer,intent(in)            :: Cx_choice
+  logical,intent(in)            :: doNcentered
+
+! Local variables
+
+  integer                       :: mu,nu,iG
+  double precision              :: b
+  double precision              :: vAO,gAO
+  double precision              :: r,g,x,dxdr,dxdg,f
+  double precision              :: a1,b1,c1,d1,w1
+  double precision              :: a2,b2,c2,d2,w2
+  double precision              :: Fx1,Fx2,Cx
+
+! Output variables
+
+  double precision,intent(out)  :: Fx(nBas,nBas)
+
+! Coefficients for B88 GGA exchange functional
+
+  b = 0.0042d0
+
+! Defining enhancements factor for weight-dependent functionals
+
+! Parameters for first state
+
+    a1 = aCC(1,1)
+    b1 = aCC(2,1)
+    c1 = aCC(3,1)
+    d1 = aCC(4,1)
+
+! Parameters for second state
+
+    a2 = aCC(1,2)
+    b2 = aCC(2,2)
+    c2 = aCC(3,2)
+    d2 = aCC(4,2)
+
+    w1 = wEns(2)
+    Fx1 = 1d0 + a1*w1 + b1*w1**2 + c1*w1**3 + d1*w1**4
+
+    w2 = wEns(3)
+    Fx2 = 1d0 + a2*w2 + b2*w2**2 + c2*w2**3 + d2*w2**4
+
+  select case (Cx_choice)
+
+    case(1)
+      Cx = Fx1
+
+    case(2)
+      Cx = Fx2
+
+    case(3)
+      Cx = Fx2*Fx1
+
+    case default
+      Cx = 1.d0
+
+  end select
+
+
+! Compute GGA exchange matrix in the AO basis
+
+  Fx(:,:) = 0d0
+
+ do mu=1,nBas
+    do nu=1,nBas
+      do iG=1,nGrid
+
+        r = max(0d0,rho(iG))
+
+        if(r > threshold) then
+
+          vAO = weight(iG)*AO(mu,iG)*AO(nu,iG)
+
+          g = drho(1,iG)**2 + drho(2,iG)**2 + drho(3,iG)**2
+          x = sqrt(g)/r**(4d0/3d0)
+          dxdr = - 4d0*sqrt(g)/(3d0*r**(7d0/3d0))/x
+          dxdg = + 1d0/(2d0*sqrt(g)*r**(4d0/3d0))/x
+
+          f = b*x**2/(1d0 + 6d0*b*x*asinh(x))
+
+          Fx(mu,nu) = Fx(mu,nu) + vAO*(                 &
+                      4d0/3d0*r**(1d0/3d0)*(CxLSDA - f) &
+                    - 2d0*r**(4d0/3d0)*dxdr*f           &
+                    + r**(4d0/3d0)*dxdr*(6d0*b*x*asinh(x) + 6d0*b*x**2/sqrt(1d0+x**2))*f/(1d0 + 6d0*b*x*asinh(x)) )
+
+          gAO = drho(1,iG)*(dAO(1,mu,iG)*AO(nu,iG) + AO(mu,iG)*dAO(1,nu,iG)) &
+              + drho(2,iG)*(dAO(2,mu,iG)*AO(nu,iG) + AO(mu,iG)*dAO(2,nu,iG)) &
+              + drho(3,iG)*(dAO(3,mu,iG)*AO(nu,iG) + AO(mu,iG)*dAO(3,nu,iG))
+          gAO = weight(iG)*gAO
+
+          Fx(mu,nu) = Fx(mu,nu) + 2d0*gAO*r**(4d0/3d0)*dxdg*(   &
+                    - 2d0*f + (6d0*b*x*asinh(x) + 6d0*b*x**2/sqrt(1d0+x**2))*f/(1d0 + 6d0*b*x*asinh(x)) )
+
+        end if
+
+      end do
+    end do
+  end do
+
+  Fx(:,:) = Cx*Fx(:,:)
+
+end subroutine CC_B88_gga_exchange_potential
+