QuAcK/src/GW/print_qsGGW.f90

subroutine print_qsGGW(nBas,nO,nSCF,Conv,thresh,eHF,eGW,c,SigC,Z,ENuc,ET,EV,EJ,Ex,EcGM,EcRPA,EqsGW,dipole)

! Print information for the generalized version of qsGW

  implicit none
  include 'parameters.h'

! Input variables

  integer,intent(in)                 :: nBas
  integer,intent(in)                 :: nO
  integer,intent(in)                 :: nSCF
  double precision,intent(in)        :: ENuc
  double precision,intent(in)        :: ET
  double precision,intent(in)        :: EV
  double precision,intent(in)        :: EJ
  double precision,intent(in)        :: Ex
  double precision,intent(in)        :: EcGM
  double precision,intent(in)        :: EcRPA
  double precision,intent(in)        :: Conv
  double precision,intent(in)        :: thresh
  double precision,intent(in)        :: eHF(nBas)
  double precision,intent(in)        :: eGW(nBas)
  double precision,intent(in)        :: c(nBas)
  double precision,intent(in)        :: SigC(nBas,nBas)
  double precision,intent(in)        :: Z(nBas)
  double precision,intent(in)        :: EqsGW
  double precision,intent(in)        :: dipole(ncart)

! Local variables

  logical                            :: dump_orb = .false.
  integer                            :: p,ixyz,HOMO,LUMO
  double precision                   :: Gap
  double precision,external          :: trace_matrix

! Output variables

! HOMO and LUMO

  HOMO = nO
  LUMO = HOMO + 1
  Gap = eGW(LUMO)-eGW(HOMO)

! Compute energies

! Dump results

  write(*,*)'-------------------------------------------------------------------------------'
  if(nSCF < 10) then
    write(*,'(1X,A22,I1,A1,I1,A12)')'  Self-consistent qsRG',nSCF,'W',nSCF,' calculation'
  elseif(nSCF < 100) then
    write(*,'(1X,A22,I2,A1,I2,A12)')'  Self-consistent qsRG',nSCF,'W',nSCF,' calculation'
  else
    write(*,'(1X,A22,I3,A1,I3,A12)')'  Self-consistent qsRG',nSCF,'W',nSCF,' calculation'
  endif
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,'(1X,A1,1X,A3,1X,A1,1X,A15,1X,A1,1X,A15,1X,A1,1X,A15,1X,A1,1X,A15,1X,A1,1X)') &
            '|','#','|','e_HF (eV)','|','Sig_GW (eV)','|','Z','|','e_GW (eV)','|'
  write(*,*)'-------------------------------------------------------------------------------'

  do p=1,nBas
    write(*,'(1X,A1,1X,I3,1X,A1,1X,F15.6,1X,A1,1X,F15.6,1X,A1,1X,F15.6,1X,A1,1X,F15.6,1X,A1,1X)') &
    '|',p,'|',eHF(p)*HaToeV,'|',SigC(p,p)*HaToeV,'|',Z(p),'|',eGW(p)*HaToeV,'|'
  enddo

  write(*,*)'-------------------------------------------------------------------------------'
  write(*,'(2X,A10,I3)')   'Iteration ',nSCF
  write(*,'(2X,A14,F15.5)')'Convergence = ',Conv
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,'(2X,A60,F15.6,A3)') 'qsGGW HOMO     energy = ',eGW(HOMO)*HaToeV,' eV'
  write(*,'(2X,A60,F15.6,A3)') 'qsGGW LUMO     energy = ',eGW(LUMO)*HaToeV,' eV'
  write(*,'(2X,A60,F15.6,A3)') 'qsGGW HOMO-LUMO gap   = ',Gap*HaToeV,' eV'
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,'(2X,A60,F15.6,A3)') '      qsGGW total       energy = ',ENuc + EqsGW,' au'
  write(*,'(2X,A60,F15.6,A3)') '      qsGGW exchange    energy = ',Ex,' au'
  write(*,'(2X,A60,F15.6,A3)') '   GM@qsGGW correlation energy = ',EcGM,' au'
  write(*,'(2X,A60,F15.6,A3)') 'phRPA@qsGGW correlation energy = ',EcRPA,' au'
  write(*,*)'-------------------------------------------------------------------------------'
  write(*,*)

! Dump results for final iteration

  if(Conv < thresh) then

    write(*,*)
    write(*,'(A50)')           '---------------------------------------'
    write(*,'(A33)')           ' Summary              '
    write(*,'(A50)')           '---------------------------------------'
    write(*,'(A33,1X,F16.10,A3)') ' One-electron energy = ',ET + EV,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Kinetic      energy = ',ET,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Potential    energy = ',EV,' au'
    write(*,'(A50)')           '---------------------------------------'
    write(*,'(A33,1X,F16.10,A3)') ' Two-electron energy = ',EJ + Ex,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Hartree      energy = ',EJ,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Exchange     energy = ',Ex,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Correlation  energy = ',EcGM,' au'
    write(*,'(A50)')           '---------------------------------------'
    write(*,'(A33,1X,F16.10,A3)') ' Electronic   energy = ',EqsGW,' au'
    write(*,'(A33,1X,F16.10,A3)') ' Nuclear   repulsion = ',ENuc,' au'
    write(*,'(A33,1X,F16.10,A3)') ' qsGGW        energy = ',ENuc + EqsGW,' au'
    write(*,'(A50)')           '---------------------------------------'
    write(*,'(A36)')           ' Dipole moment (Debye)    '
    write(*,'(10X,4A10)')      'X','Y','Z','Tot.'
    write(*,'(10X,4F10.4)')    (dipole(ixyz)*auToD,ixyz=1,ncart),norm2(dipole)*auToD
    write(*,'(A50)')           '-----------------------------------------'
    write(*,*)
 
    if(dump_orb) then
      write(*,'(A50)') '---------------------------------------'
      write(*,'(A32)') ' Generalized qsGW orbital coefficients '
      write(*,'(A50)') '---------------------------------------'
      call matout(nBas,nBas,c)
      write(*,*)
    end if
    write(*,'(A50)') '---------------------------------------'
    write(*,'(A32)') ' Generalized qsGW orbital energies (au)'
    write(*,'(A50)') '---------------------------------------'
    call vecout(nBas,eGW)
    write(*,*)

  endif


end subroutine