quack/src/eDFT/UCC_lda_exchange_individual_energy.f90

subroutine UCC_lda_exchange_individual_energy(nEns,wEns,aCC_w1,aCC_w2,nGrid,weight,rhow,rho,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)
  double precision,intent(in)   :: aCC_w1(3)
  double precision,intent(in)   :: aCC_w2(3)
  integer,intent(in)            :: nGrid
  double precision,intent(in)   :: weight(nGrid)
  double precision,intent(in)   :: rhow(nGrid)
  double precision,intent(in)   :: rho(nGrid)

! Local variables

  integer                       :: iG
  double precision              :: r,rI,alpha
  double precision              :: e_p,dedr

  double precision              :: a1,b1,c1,w1
  double precision              :: a2,b2,c2,w2
  double precision              :: Fx1,Fx2,Cx

! Output variables

  double precision,intent(out)  :: Ex

! Single excitation parameter

!  a1 = 0.0d0
!  b1 = 0.0d0
!  c1 = 0.0d0

! Parameters for H2 at equilibrium

! a2 = +0.5751782560799208d0
! b2 = -0.021108186591137282d0
! c2 = -0.36718902716347124d0

! Parameters for stretch H2

!  a2 = + 0.01922622507087411d0
!  b2 = - 0.01799647558018601d0
!  c2 = - 0.022945430666782573d0

! Parameters for He

! a2 = 1.9125735895875828d0
! b2 = 2.715266992840757d0
! c2 = 2.1634223380633086d0

! Parameters for He N -> N-1

  a1 = aCC_w1(1)
  b1 = aCC_w1(2)
  c1 = aCC_w1(3)

! Parameters for He N -> N+1

  a2 = aCC_w2(1)
  b2 = aCC_w2(2)
  c2 = aCC_w2(3)

! Cx coefficient for unrestricted Slater LDA exchange

  alpha = -(3d0/2d0)*(3d0/(4d0*pi))**(1d0/3d0)

  w1 = wEns(2)
  Fx1 = 1d0 - w1*(1d0 - w1)*(a1 + b1*(w1 - 0.5d0) + c1*(w1 - 0.5d0)**2)

  w2 = wEns(3)
  Fx2 = 1d0 - w2*(1d0 - w2)*(a2 + b2*(w2 - 0.5d0) + c2*(w2 - 0.5d0)**2)

  Cx = alpha*Fx1*Fx2

! Compute LDA exchange matrix in the AO basis

  Ex = 0d0
  do iG=1,nGrid

    r  = max(0d0,rhow(iG))
    rI = max(0d0,rho(iG))

    if(r > threshold) then

      e_p  =         Cx*r**(1d0/3d0)
      dedr = 1d0/3d0*Cx*r**(-2d0/3d0)

      Ex = Ex - weight(iG)*dedr*r*r

      if(rI > threshold) then

      Ex = Ex + weight(iG)*(e_p*rI + dedr*r*rI)

      endif

    endif

  enddo

end subroutine UCC_lda_exchange_individual_energy
modifications for the parameters of the weight-dependent functionnals 2020-07-02 18:49:42 +02:00			`subroutine UCC_lda_exchange_individual_energy(nEns,wEns,aCC_w1,aCC_w2,nGrid,weight,rhow,rho,Ex)`
clean up unrestricted 2020-07-02 14:27:38 +02:00
			`! 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)`
more modifications in the final print for eDFT_UKS 2020-07-02 22:15:29 +02:00			`double precision,intent(in) :: aCC_w1(3)`
			`double precision,intent(in) :: aCC_w2(3)`
clean up unrestricted 2020-07-02 14:27:38 +02:00			`integer,intent(in) :: nGrid`
			`double precision,intent(in) :: weight(nGrid)`
			`double precision,intent(in) :: rhow(nGrid)`
			`double precision,intent(in) :: rho(nGrid)`

			`! Local variables`

			`integer :: iG`
			`double precision :: r,rI,alpha`
			`double precision :: e_p,dedr`

			`double precision :: a1,b1,c1,w1`
			`double precision :: a2,b2,c2,w2`
			`double precision :: Fx1,Fx2,Cx`

			`! Output variables`

			`double precision,intent(out) :: Ex`

			`! Single excitation parameter`

			`! a1 = 0.0d0`
			`! b1 = 0.0d0`
			`! c1 = 0.0d0`

			`! Parameters for H2 at equilibrium`

			`! a2 = +0.5751782560799208d0`
			`! b2 = -0.021108186591137282d0`
			`! c2 = -0.36718902716347124d0`

			`! Parameters for stretch H2`

			`! a2 = + 0.01922622507087411d0`
			`! b2 = - 0.01799647558018601d0`
			`! c2 = - 0.022945430666782573d0`

			`! Parameters for He`

			`! a2 = 1.9125735895875828d0`
			`! b2 = 2.715266992840757d0`
			`! c2 = 2.1634223380633086d0`

			`! Parameters for He N -> N-1`

modifications for the parameters of the weight-dependent functionnals 2020-07-02 18:49:42 +02:00			`a1 = aCC_w1(1)`
			`b1 = aCC_w1(2)`
			`c1 = aCC_w1(3)`
clean up unrestricted 2020-07-02 14:27:38 +02:00
			`! Parameters for He N -> N+1`

modifications for the parameters of the weight-dependent functionnals 2020-07-02 18:49:42 +02:00			`a2 = aCC_w2(1)`
			`b2 = aCC_w2(2)`
			`c2 = aCC_w2(3)`
clean up unrestricted 2020-07-02 14:27:38 +02:00
			`! Cx coefficient for unrestricted Slater LDA exchange`

			`alpha = -(3d0/2d0)(3d0/(4d0pi))**(1d0/3d0)`

			`w1 = wEns(2)`
			`Fx1 = 1d0 - w1(1d0 - w1)(a1 + b1(w1 - 0.5d0) + c1(w1 - 0.5d0)**2)`

			`w2 = wEns(3)`
			`Fx2 = 1d0 - w2(1d0 - w2)(a2 + b2(w2 - 0.5d0) + c2(w2 - 0.5d0)**2)`

			`Cx = alphaFx1Fx2`

			`! Compute LDA exchange matrix in the AO basis`

			`Ex = 0d0`
			`do iG=1,nGrid`

			`r = max(0d0,rhow(iG))`
			`rI = max(0d0,rho(iG))`

fix problem with individual energies 2020-07-08 10:55:03 +02:00			`if(r > threshold) then`
clean up unrestricted 2020-07-02 14:27:38 +02:00
			`e_p = Cxr*(1d0/3d0)`
			`dedr = 1d0/3d0Cxr**(-2d0/3d0)`
fix problem with individual energies 2020-07-08 10:55:03 +02:00
			`Ex = Ex - weight(iG)dedrr*r`

			`if(rI > threshold) then`

			`Ex = Ex + weight(iG)(e_prI + dedrrrI)`

			`endif`
clean up unrestricted 2020-07-02 14:27:38 +02:00
			`endif`

			`enddo`

			`end subroutine UCC_lda_exchange_individual_energy`