quack/src/RPA/RPAx.f90

subroutine RPAx(TDA,doACFDT,exchange_kernel,singlet,triplet,eta,nBas,nC,nO,nV,nR,nS,ENuc,ERHF, & 
                ERI,dipole_int,eHF)

! Perform random phase approximation calculation with exchange (aka TDHF)

  implicit none
  include 'parameters.h'
  include 'quadrature.h'

! Input variables

  logical,intent(in)            :: TDA
  logical,intent(in)            :: doACFDT
  logical,intent(in)            :: exchange_kernel
  logical,intent(in)            :: singlet
  double precision,intent(in)   :: eta
  logical,intent(in)            :: triplet
  integer,intent(in)            :: nBas
  integer,intent(in)            :: nC
  integer,intent(in)            :: nO
  integer,intent(in)            :: nV
  integer,intent(in)            :: nR
  integer,intent(in)            :: nS
  double precision,intent(in)   :: ENuc
  double precision,intent(in)   :: ERHF
  double precision,intent(in)   :: eHF(nBas)
  double precision,intent(in)   :: ERI(nBas,nBas,nBas,nBas)
  double precision,intent(in)   :: dipole_int(nBas,nBas,ncart)

! Local variables

  integer                       :: ispin
  double precision,allocatable  :: Omega(:,:)
  double precision,allocatable  :: XpY(:,:,:)
  double precision,allocatable  :: XmY(:,:,:)

  double precision              :: rho
  double precision              :: EcRPAx(nspin)
  double precision              :: EcAC(nspin)

! Hello world

  write(*,*)
  write(*,*)'***********************************************************'
  write(*,*)'|  Random phase approximation calculation with exchange   |'
  write(*,*)'***********************************************************'
  write(*,*)

! TDA 

  if(TDA) then
    write(*,*) 'Tamm-Dancoff approximation activated!'
    write(*,*) ' => RPAx + TDA = CIS '
    write(*,*)
  end if

! Initialization

  EcRPAx(:) = 0d0
  EcAC(:)   = 0d0

! Memory allocation

  allocate(Omega(nS,nspin),XpY(nS,nS,nspin),XmY(nS,nS,nspin))

! Singlet manifold

  if(singlet) then 

    ispin = 1

    call linear_response(ispin,.false.,TDA,.false.,eta,nBas,nC,nO,nV,nR,nS,1d0,eHF,ERI,Omega(:,ispin),rho, &
                         EcRPAx(ispin),Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))
    call print_excitation('RPAx@HF     ',ispin,nS,Omega(:,ispin))
    call print_transition_vectors(.true.,nBas,nC,nO,nV,nR,nS,dipole_int,Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))

  endif

! Triplet manifold 

  if(triplet) then 

    ispin = 2

    call linear_response(ispin,.false.,TDA,.false.,eta,nBas,nC,nO,nV,nR,nS,1d0,eHF,ERI,Omega(:,ispin),rho, &
                         EcRPAx(ispin),Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))
    call print_excitation('RPAx@HF     ',ispin,nS,Omega(:,ispin))
    call print_transition_vectors(.false.,nBas,nC,nO,nV,nR,nS,dipole_int,Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))

  endif

  if(exchange_kernel) then

    EcRPAx(1) = 0.5d0*EcRPAx(1)
    EcRPAx(2) = 1.5d0*EcRPAx(2)

  end if

  write(*,*)
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy (singlet) =',EcRPAx(1)
  write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy (triplet) =',EcRPAx(2)
  write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy           =',EcRPAx(1) + EcRPAx(2)
  write(*,'(2X,A50,F20.10)') 'Tr@RPAx total energy                 =',ENuc + ERHF + EcRPAx(1) + EcRPAx(2)
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,*)

! Compute the correlation energy via the adiabatic connection 

  if(doACFDT) then

    write(*,*) '-------------------------------------------------------'
    write(*,*) 'Adiabatic connection version of RPAx correlation energy'
    write(*,*) '-------------------------------------------------------'
    write(*,*)

    call ACFDT(exchange_kernel,.false.,.false.,.false.,TDA,.false.,singlet,triplet,eta, &
               nBas,nC,nO,nV,nR,nS,ERI,eHF,eHF,EcAC)

    write(*,*)
    write(*,*)'-------------------------------------------------------------------------------'
    write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy (singlet) =',EcAC(1)
    write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy (triplet) =',EcAC(2)
    write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy           =',EcAC(1) + EcAC(2)
    write(*,'(2X,A50,F20.10)') 'AC@RPAx total energy                 =',ENuc + ERHF + EcAC(1) + EcAC(2)
    write(*,*)'-------------------------------------------------------------------------------'
    write(*,*)

  end if

end subroutine RPAx
oscillator strength and dipole integrals 2020-09-28 21:25:25 +02:00			`subroutine RPAx(TDA,doACFDT,exchange_kernel,singlet,triplet,eta,nBas,nC,nO,nV,nR,nS,ENuc,ERHF, &`
			`ERI,dipole_int,eHF)`
RPAx 2020-01-28 09:00:11 +01:00
			`! Perform random phase approximation calculation with exchange (aka TDHF)`

			`implicit none`
			`include 'parameters.h'`
			`include 'quadrature.h'`

			`! Input variables`

spin flip 2020-09-24 16:39:15 +02:00			`logical,intent(in) :: TDA`
RPAx 2020-01-28 09:00:11 +01:00			`logical,intent(in) :: doACFDT`
			`logical,intent(in) :: exchange_kernel`
URPA 2020-09-23 09:46:44 +02:00			`logical,intent(in) :: singlet`
RPAx 2020-01-28 09:00:11 +01:00			`double precision,intent(in) :: eta`
URPA 2020-09-23 09:46:44 +02:00			`logical,intent(in) :: triplet`
RPAx 2020-01-28 09:00:11 +01:00			`integer,intent(in) :: nBas`
			`integer,intent(in) :: nC`
			`integer,intent(in) :: nO`
			`integer,intent(in) :: nV`
			`integer,intent(in) :: nR`
			`integer,intent(in) :: nS`
			`double precision,intent(in) :: ENuc`
			`double precision,intent(in) :: ERHF`
big cleaning 2020-09-24 11:56:06 +02:00			`double precision,intent(in) :: eHF(nBas)`
RPAx 2020-01-28 09:00:11 +01:00			`double precision,intent(in) :: ERI(nBas,nBas,nBas,nBas)`
oscillator strength and dipole integrals 2020-09-28 21:25:25 +02:00			`double precision,intent(in) :: dipole_int(nBas,nBas,ncart)`
RPAx 2020-01-28 09:00:11 +01:00
			`! Local variables`

			`integer :: ispin`
			`double precision,allocatable :: Omega(:,:)`
			`double precision,allocatable :: XpY(:,:,:)`
			`double precision,allocatable :: XmY(:,:,:)`

			`double precision :: rho`
			`double precision :: EcRPAx(nspin)`
			`double precision :: EcAC(nspin)`

			`! Hello world`

			`write(,)`
			`write(,)'***********************************************************'`
			`write(,)'\| Random phase approximation calculation with exchange \|'`
			`write(,)'***********************************************************'`
			`write(,)`

debugging sf 2020-09-30 09:59:18 +02:00			`! TDA`

			`if(TDA) then`
			`write(,) 'Tamm-Dancoff approximation activated!'`
			`write(,) ' => RPAx + TDA = CIS '`
			`write(,)`
			`end if`

RPAx 2020-01-28 09:00:11 +01:00			`! Initialization`

			`EcRPAx(:) = 0d0`
			`EcAC(:) = 0d0`

			`! Memory allocation`

			`allocate(Omega(nS,nspin),XpY(nS,nS,nspin),XmY(nS,nS,nspin))`

			`! Singlet manifold`

URPA 2020-09-23 09:46:44 +02:00			`if(singlet) then`
RPAx 2020-01-28 09:00:11 +01:00
			`ispin = 1`

spin flip 2020-09-24 16:39:15 +02:00			`call linear_response(ispin,.false.,TDA,.false.,eta,nBas,nC,nO,nV,nR,nS,1d0,eHF,ERI,Omega(:,ispin),rho, &`
RPAx 2020-01-28 09:00:11 +01:00			`EcRPAx(ispin),Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))`
big cleaning 2020-09-24 11:56:06 +02:00			`call print_excitation('RPAx@HF ',ispin,nS,Omega(:,ispin))`
oscillator strength and dipole integrals 2020-09-28 21:25:25 +02:00			`call print_transition_vectors(.true.,nBas,nC,nO,nV,nR,nS,dipole_int,Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))`
(1) 2020-06-05 22:34:32 +02:00
RPAx 2020-01-28 09:00:11 +01:00			`endif`

			`! Triplet manifold`

URPA 2020-09-23 09:46:44 +02:00			`if(triplet) then`
RPAx 2020-01-28 09:00:11 +01:00
			`ispin = 2`

fix bug RPAx 2021-03-04 15:09:56 +01:00			`call linear_response(ispin,.false.,TDA,.false.,eta,nBas,nC,nO,nV,nR,nS,1d0,eHF,ERI,Omega(:,ispin),rho, &`
RPAx 2020-01-28 09:00:11 +01:00			`EcRPAx(ispin),Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))`
big cleaning 2020-09-24 11:56:06 +02:00			`call print_excitation('RPAx@HF ',ispin,nS,Omega(:,ispin))`
oscillator strength and dipole integrals 2020-09-28 21:25:25 +02:00			`call print_transition_vectors(.false.,nBas,nC,nO,nV,nR,nS,dipole_int,Omega(:,ispin),XpY(:,:,ispin),XmY(:,:,ispin))`
RPAx 2020-01-28 09:00:11 +01:00
			`endif`

			`if(exchange_kernel) then`

			`EcRPAx(1) = 0.5d0*EcRPAx(1)`
			`EcRPAx(2) = 1.5d0*EcRPAx(2)`

			`end if`

			`write(,)`
			`write(,)'-------------------------------------------------------------------------------'`
			`write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy (singlet) =',EcRPAx(1)`
			`write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy (triplet) =',EcRPAx(2)`
			`write(*,'(2X,A50,F20.10)') 'Tr@RPAx correlation energy =',EcRPAx(1) + EcRPAx(2)`
			`write(*,'(2X,A50,F20.10)') 'Tr@RPAx total energy =',ENuc + ERHF + EcRPAx(1) + EcRPAx(2)`
			`write(,)'-------------------------------------------------------------------------------'`
			`write(,)`

			`! Compute the correlation energy via the adiabatic connection`

			`if(doACFDT) then`

			`write(,) '-------------------------------------------------------'`
			`write(,) 'Adiabatic connection version of RPAx correlation energy'`
			`write(,) '-------------------------------------------------------'`
			`write(,)`

spin flip 2020-09-24 16:39:15 +02:00			`call ACFDT(exchange_kernel,.false.,.false.,.false.,TDA,.false.,singlet,triplet,eta, &`
big cleaning 2020-09-24 11:56:06 +02:00			`nBas,nC,nO,nV,nR,nS,ERI,eHF,eHF,EcAC)`
RPAx 2020-01-28 09:00:11 +01:00
			`write(,)`
			`write(,)'-------------------------------------------------------------------------------'`
			`write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy (singlet) =',EcAC(1)`
			`write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy (triplet) =',EcAC(2)`
			`write(*,'(2X,A50,F20.10)') 'AC@RPAx correlation energy =',EcAC(1) + EcAC(2)`
			`write(*,'(2X,A50,F20.10)') 'AC@RPAx total energy =',ENuc + ERHF + EcAC(1) + EcAC(2)`
			`write(,)'-------------------------------------------------------------------------------'`
			`write(,)`

			`end if`

			`end subroutine RPAx`