mirror of
https://github.com/pfloos/quack
synced 2024-11-07 06:33:55 +01:00
working on RPA third channel
This commit is contained in:
parent
e13c9866fb
commit
cec0fe9205
@ -5,17 +5,17 @@
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# CCD DCD CCSD CCSD(T)
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F F F F
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# drCCD rCCD lCCD pCCD
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F F F F
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T T F F
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# CIS* CIS(D) CID CISD FCI
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F F F F F
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# RPA* RPAx* ppRPA
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F F F
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T T F
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# G0F2* evGF2* qsGF2* G0F3 evGF3
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T F F F F
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F F F F F
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# G0W0* evGW* qsGW* ufG0W0 ufGW
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T F F F F
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F F F F F
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# G0T0 evGT qsGT
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T F F
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F F F
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# MCMP2
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F
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# * unrestricted version available
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@ -5,7 +5,7 @@
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# CC: maxSCF thresh DIIS n_diis
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64 0.0000000001 T 5
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# spin: TDA singlet triplet spin_conserved spin_flip
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F T F T T
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F T T T T
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# GF: maxSCF thresh DIIS n_diis lin eta renorm
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256 0.00001 T 5 T 0.00367493 3
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# GW/GT: maxSCF thresh DIIS n_diis lin eta COHSEX SOSEX TDA_W G0W GW0
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@ -1,4 +1,4 @@
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2
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H 0. 0. 0.
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H 0. -0.740848 0.740848
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H 0. 0. 2.000000
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@ -220,6 +220,15 @@ subroutine CCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF,e
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endif
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write(*,*)
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write(*,*)'----------------------------------------------------'
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write(*,*)' CCD energy '
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write(*,*)'----------------------------------------------------'
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write(*,'(1X,A30,1X,F15.10)')' E(CCD) = ',ECCD
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write(*,'(1X,A30,1X,F15.10)')' Ec(CCD) = ',EcCCD
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write(*,*)'----------------------------------------------------'
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write(*,*)
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! Moller-Plesset energies
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write(*,*)
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237
src/CC/crCCD.f90
Normal file
237
src/CC/crCCD.f90
Normal file
@ -0,0 +1,237 @@
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subroutine crCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF,eHF)
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! Crossed-ring CCD module
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implicit none
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! Input variables
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integer,intent(in) :: maxSCF
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integer,intent(in) :: max_diis
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double precision,intent(in) :: thresh
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integer,intent(in) :: nBasin
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integer,intent(in) :: nCin
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integer,intent(in) :: nOin
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integer,intent(in) :: nVin
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integer,intent(in) :: nRin
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double precision,intent(in) :: ENuc,ERHF
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double precision,intent(in) :: eHF(nBasin)
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double precision,intent(in) :: ERI(nBasin,nBasin,nBasin,nBasin)
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! Local variables
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integer :: nBas
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integer :: nC
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integer :: nO
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integer :: nV
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integer :: nR
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integer :: nSCF
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double precision :: Conv
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double precision :: EcMP2
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double precision :: ECCD,EcCCD
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double precision,allocatable :: seHF(:)
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double precision,allocatable :: sERI(:,:,:,:)
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double precision,allocatable :: dbERI(:,:,:,:)
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double precision,allocatable :: eO(:)
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double precision,allocatable :: eV(:)
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double precision,allocatable :: delta_OOVV(:,:,:,:)
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double precision,allocatable :: OOOO(:,:,:,:)
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double precision,allocatable :: OOVV(:,:,:,:)
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double precision,allocatable :: OVOV(:,:,:,:)
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double precision,allocatable :: OVVO(:,:,:,:)
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double precision,allocatable :: VVVV(:,:,:,:)
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double precision,allocatable :: X1(:,:,:,:)
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double precision,allocatable :: X2(:,:)
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double precision,allocatable :: X3(:,:)
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double precision,allocatable :: X4(:,:,:,:)
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double precision,allocatable :: u(:,:,:,:)
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double precision,allocatable :: v(:,:,:,:)
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double precision,allocatable :: r2r(:,:,:,:)
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double precision,allocatable :: r2l(:,:,:,:)
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double precision,allocatable :: r2(:,:,:,:)
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double precision,allocatable :: t2(:,:,:,:)
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integer :: n_diis
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double precision :: rcond
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double precision,allocatable :: error_diis(:,:)
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double precision,allocatable :: t_diis(:,:)
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! Hello world
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write(*,*)
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write(*,*)'**************************************'
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write(*,*)'| crossed-ring CCD calculation |'
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write(*,*)'**************************************'
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write(*,*)
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! Spatial to spin orbitals
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nBas = 2*nBasin
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nC = 2*nCin
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nO = 2*nOin
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nV = 2*nVin
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nR = 2*nRin
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allocate(seHF(nBas),sERI(nBas,nBas,nBas,nBas))
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call spatial_to_spin_MO_energy(nBasin,eHF,nBas,seHF)
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call spatial_to_spin_ERI(nBasin,ERI,nBas,sERI)
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! Antysymmetrize ERIs
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allocate(dbERI(nBas,nBas,nBas,nBas))
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call antisymmetrize_ERI(2,nBas,sERI,dbERI)
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deallocate(sERI)
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! Form energy denominator
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allocate(eO(nO),eV(nV))
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allocate(delta_OOVV(nO,nO,nV,nV))
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eO(:) = seHF(1:nO)
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eV(:) = seHF(nO+1:nBas)
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call form_delta_OOVV(nC,nO,nV,nR,eO,eV,delta_OOVV)
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deallocate(seHF)
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! Create integral batches
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allocate(OOOO(nO,nO,nO,nO),OOVV(nO,nO,nV,nV),OVOV(nO,nV,nO,nV),VVVV(nV,nV,nV,nV),OVVO(nO,nV,nV,nO))
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OOOO(:,:,:,:) = dbERI( 1:nO , 1:nO , 1:nO , 1:nO )
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OOVV(:,:,:,:) = dbERI( 1:nO , 1:nO ,nO+1:nBas,nO+1:nBas)
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OVOV(:,:,:,:) = dbERI( 1:nO ,nO+1:nBas, 1:nO ,nO+1:nBas)
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OVVO(:,:,:,:) = dbERI( 1:nO ,nO+1:nBas,nO+1:nBas, 1:nO )
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VVVV(:,:,:,:) = dbERI(nO+1:nBas,nO+1:nBas,nO+1:nBas,nO+1:nBas)
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deallocate(dbERI)
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! MP2 guess amplitudes
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allocate(t2(nO,nO,nV,nV))
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t2(:,:,:,:) = -OOVV(:,:,:,:)/delta_OOVV(:,:,:,:)
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call CCD_correlation_energy(nC,nO,nV,nR,OOVV,t2,EcMP2)
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! Memory allocation for DIIS
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allocate(error_diis(nO*nO*nV*nV,max_diis),t_diis(nO*nO*nV*nV,max_diis))
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! Initialization
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allocate(r2(nO,nO,nV,nV),u(nO,nO,nV,nV),v(nO,nO,nV,nV))
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allocate(r2r(nO,nO,nV,nV),r2l(nO,nO,nV,nV))
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allocate(X1(nO,nO,nO,nO),X2(nV,nV),X3(nO,nO),X4(nO,nO,nV,nV))
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Conv = 1d0
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nSCF = 0
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n_diis = 0
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t_diis(:,:) = 0d0
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error_diis(:,:) = 0d0
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!------------------------------------------------------------------------
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! Main SCF loop
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!------------------------------------------------------------------------
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write(*,*)
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write(*,*)'----------------------------------------------------'
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write(*,*)'| crossed-ring CCD calculation |'
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write(*,*)'----------------------------------------------------'
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write(*,'(1X,A1,1X,A3,1X,A1,1X,A16,1X,A1,1X,A10,1X,A1,1X,A10,1X,A1,1X)') &
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'|','#','|','E(CCD)','|','Ec(CCD)','|','Conv','|'
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write(*,*)'----------------------------------------------------'
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do while(Conv > thresh .and. nSCF < maxSCF)
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! Increment
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nSCF = nSCF + 1
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! Compute residual
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! Form linear array
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call form_u(nC,nO,nV,nR,OOOO,VVVV,OVOV,t2,u)
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! Form interemediate arrays
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call form_X(nC,nO,nV,nR,OOVV,t2,X1,X2,X3,X4)
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! Form quadratic array
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call form_v(nC,nO,nV,nR,X1,X2,X3,X4,t2,v)
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call form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2r)
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call form_ladder_r(nC,nO,nV,nR,OOOO,OOVV,VVVV,t2,r2l)
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r2(:,:,:,:) = OOVV(:,:,:,:) + delta_OOVV(:,:,:,:)*t2(:,:,:,:) + u(:,:,:,:) + v(:,:,:,:) - r2r(:,:,:,:) - r2l(:,:,:,:)
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! Check convergence
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Conv = maxval(abs(r2(nC+1:nO,nC+1:nO,1:nV-nR,1:nV-nR)))
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! Update amplitudes
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t2(:,:,:,:) = t2(:,:,:,:) - r2(:,:,:,:)/delta_OOVV(:,:,:,:)
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! Compute correlation energy
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call CCD_correlation_energy(nC,nO,nV,nR,OOVV,t2,EcCCD)
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! Dump results
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ECCD = ERHF + EcCCD
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! DIIS extrapolation
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n_diis = min(n_diis+1,max_diis)
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call DIIS_extrapolation(rcond,nO*nO*nV*nV,nO*nO*nV*nV,n_diis,error_diis,t_diis,-r2/delta_OOVV,t2)
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! Reset DIIS if required
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if(abs(rcond) < 1d-15) n_diis = 0
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write(*,'(1X,A1,1X,I3,1X,A1,1X,F16.10,1X,A1,1X,F10.6,1X,A1,1X,F10.6,1X,A1,1X)') &
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'|',nSCF,'|',ECCD+ENuc,'|',EcCCD,'|',Conv,'|'
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enddo
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write(*,*)'----------------------------------------------------'
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!------------------------------------------------------------------------
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! End of SCF loop
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!------------------------------------------------------------------------
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! Did it actually converge?
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if(nSCF == maxSCF) then
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write(*,*)
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write(*,*)'!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!'
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write(*,*)' Convergence failed '
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write(*,*)'!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!'
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write(*,*)
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stop
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endif
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write(*,*)
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write(*,*)'----------------------------------------------------'
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write(*,*)' crossed-ring CCD energy '
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write(*,*)'----------------------------------------------------'
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write(*,'(1X,A30,1X,F15.10)')' E(crCCD) = ',ECCD
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write(*,'(1X,A30,1X,F15.10)')' Ec(crCCD) = ',EcCCD
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write(*,*)'----------------------------------------------------'
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write(*,*)
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end subroutine crCCD
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@ -39,6 +39,7 @@ subroutine drCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF
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double precision,allocatable :: OOVV(:,:,:,:)
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double precision,allocatable :: OVVO(:,:,:,:)
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double precision,allocatable :: VOOV(:,:,:,:)
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double precision,allocatable :: r2(:,:,:,:)
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double precision,allocatable :: t2(:,:,:,:)
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@ -84,10 +85,11 @@ subroutine drCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF
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! Create integral batches
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allocate(OOVV(nO,nO,nV,nV),OVVO(nO,nV,nV,nO))
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allocate(OOVV(nO,nO,nV,nV),OVVO(nO,nV,nV,nO),VOOV(nV,nO,nO,nV))
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OOVV(:,:,:,:) = sERI( 1:nO , 1:nO ,nO+1:nBas,nO+1:nBas)
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OVVO(:,:,:,:) = sERI( 1:nO ,nO+1:nBas,nO+1:nBas, 1:nO )
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VOOV(:,:,:,:) = sERI(nO+1:nBas, 1:nO , 1:nO ,nO+1:nBas)
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deallocate(sERI)
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@ -133,7 +135,7 @@ subroutine drCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF
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! Compute residual
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call form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2)
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call form_ring_r(nC,nO,nV,nR,OVVO,VOOV,OOVV,t2,r2)
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r2(:,:,:,:) = OOVV(:,:,:,:) + delta_OOVV(:,:,:,:)*t2(:,:,:,:) + r2(:,:,:,:)
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@ -1,4 +1,4 @@
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subroutine form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2)
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subroutine form_ring_r(nC,nO,nV,nR,OVVO,VOOV,OOVV,t2,r2)
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! Form residuals for ring CCD
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@ -9,6 +9,7 @@ subroutine form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2)
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integer,intent(in) :: nC,nO,nV,nR
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double precision,intent(in) :: t2(nO,nO,nV,nV)
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double precision,intent(in) :: OVVO(nO,nV,nV,nO)
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double precision,intent(in) :: VOOV(nV,nO,nO,nV)
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double precision,intent(in) :: OOVV(nO,nO,nV,nV)
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! Local variables
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@ -49,7 +50,7 @@ subroutine form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2)
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do k=nC+1,nO
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do c=1,nV-nR
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r2(i,j,a,b) = r2(i,j,a,b) + OVVO(i,c,a,k)*t2(k,j,c,b) + OVVO(j,c,b,k)*t2(i,k,a,c)
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r2(i,j,a,b) = r2(i,j,a,b) + VOOV(a,k,i,c)*t2(k,j,c,b) + OVVO(k,b,c,j)*t2(i,k,a,c)
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end do
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end do
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@ -40,6 +40,7 @@ subroutine rCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF,
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double precision,allocatable :: OOVV(:,:,:,:)
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double precision,allocatable :: OVVO(:,:,:,:)
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double precision,allocatable :: VOOV(:,:,:,:)
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double precision,allocatable :: r2(:,:,:,:)
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double precision,allocatable :: t2(:,:,:,:)
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@ -92,10 +93,11 @@ subroutine rCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF,
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! Create integral batches
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allocate(OOVV(nO,nO,nV,nV),OVVO(nO,nV,nV,nO))
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allocate(OOVV(nO,nO,nV,nV),OVVO(nO,nV,nV,nO),VOOV(nV,nO,nO,nV))
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OOVV(:,:,:,:) = dbERI( 1:nO , 1:nO ,nO+1:nBas,nO+1:nBas)
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OVVO(:,:,:,:) = dbERI( 1:nO ,nO+1:nBas,nO+1:nBas, 1:nO )
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VOOV(:,:,:,:) = dbERI(nO+1:nBas, 1:nO , 1:nO ,nO+1:nBas)
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deallocate(dbERI)
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@ -141,7 +143,7 @@ subroutine rCCD(maxSCF,thresh,max_diis,nBasin,nCin,nOin,nVin,nRin,ERI,ENuc,ERHF,
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! Compute residual
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call form_ring_r(nC,nO,nV,nR,OVVO,OOVV,t2,r2)
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call form_ring_r(nC,nO,nV,nR,OVVO,VOOV,OOVV,t2,r2)
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r2(:,:,:,:) = OOVV(:,:,:,:) + delta_OOVV(:,:,:,:)*t2(:,:,:,:) + r2(:,:,:,:)
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@ -1,4 +1,4 @@
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subroutine Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,lambda,eGW,OmRPA,rho_RPA,OmBSE,A_dyn)
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subroutine Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,lambda,eGW,OmRPA,rho_RPA,OmBSE,A_dyn,ZA_dyn)
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! Compute the dynamic part of the Bethe-Salpeter equation matrices
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@ -25,10 +25,12 @@ subroutine Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,lambda,eGW,Om
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! Output variables
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||||
double precision,intent(out) :: A_dyn(nS,nS)
|
||||
double precision,intent(out) :: ZA_dyn(nS,nS)
|
||||
|
||||
! Initialization
|
||||
|
||||
A_dyn(:,:) = 0d0
|
||||
ZA_dyn(:,:) = 0d0
|
||||
|
||||
! Number of poles taken into account
|
||||
|
||||
@ -67,6 +69,19 @@ subroutine Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,lambda,eGW,Om
|
||||
|
||||
A_dyn(ia,jb) = A_dyn(ia,jb) - 2d0*lambda*chi
|
||||
|
||||
chi = 0d0
|
||||
do kc=1,maxS
|
||||
|
||||
eps = + OmBSE - OmRPA(kc) - (eGW(a) - eGW(j))
|
||||
chi = chi + rho_RPA(i,j,kc)*rho_RPA(a,b,kc)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
|
||||
eps = + OmBSE - OmRPA(kc) - (eGW(b) - eGW(i))
|
||||
chi = chi + rho_RPA(i,j,kc)*rho_RPA(a,b,kc)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
|
||||
enddo
|
||||
|
||||
ZA_dyn(ia,jb) = ZA_dyn(ia,jb) + 2d0*lambda*chi
|
||||
|
||||
enddo
|
||||
enddo
|
||||
enddo
|
||||
|
@ -88,11 +88,7 @@ subroutine Bethe_Salpeter_Tmatrix_dynamic_perturbation(dTDA,eta,nBas,nC,nO,nV,nR
|
||||
|
||||
! Resonant part of the BSE correction for dynamical TDA
|
||||
|
||||
call dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,1d0,eGT,Omega1,Omega2,rho1,rho2,OmBSE(ia),Ap_dyn)
|
||||
|
||||
! Renormalization factor of the resonant parts for dynamical TDA
|
||||
|
||||
call dynamic_Tmatrix_ZA(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,1d0,eGT,Omega1,Omega2,rho1,rho2,OmBSE(ia),ZAp_dyn)
|
||||
call dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,1d0,eGT,Omega1,Omega2,rho1,rho2,OmBSE(ia),Ap_dyn,Zap_dyn)
|
||||
|
||||
ZDyn(ia) = dot_product(X,matmul(ZAp_dyn,X))
|
||||
OmDyn(ia) = dot_product(X,matmul( Ap_dyn,X))
|
||||
|
@ -82,11 +82,7 @@ subroutine Bethe_Salpeter_dynamic_perturbation(dTDA,eta,nBas,nC,nO,nV,nR,nS,eW,e
|
||||
|
||||
! Resonant part of the BSE correction for dynamical TDA
|
||||
|
||||
call Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,1d0,eGW,OmRPA,rho_RPA,OmBSE(ia),Ap_dyn)
|
||||
|
||||
! Renormalization factor of the resonant parts for dynamical TDA
|
||||
|
||||
call Bethe_Salpeter_ZA_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,1d0,eGW,OmRPA,rho_RPA,OmBSE(ia),ZAp_dyn)
|
||||
call Bethe_Salpeter_A_matrix_dynamic(eta,nBas,nC,nO,nV,nR,nS,1d0,eGW,OmRPA,rho_RPA,OmBSE(ia),Ap_dyn,ZAp_dyn)
|
||||
|
||||
ZDyn(ia) = dot_product(X,matmul(ZAp_dyn,X))
|
||||
OmDyn(ia) = dot_product(X,matmul( Ap_dyn,X))
|
||||
|
@ -1,4 +1,4 @@
|
||||
subroutine dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,Omega2,rho1,rho2,OmBSE,A_dyn)
|
||||
subroutine dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,Omega2,rho1,rho2,OmBSE,A_dyn,ZA_dyn)
|
||||
|
||||
! Compute the dynamic part of the Bethe-Salpeter equation matrices for GT
|
||||
|
||||
@ -37,10 +37,12 @@ subroutine dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,O
|
||||
! Output variables
|
||||
|
||||
double precision,intent(out) :: A_dyn(nS,nS)
|
||||
double precision,intent(out) :: ZA_dyn(nS,nS)
|
||||
|
||||
! Initialization
|
||||
|
||||
A_dyn(:,:) = 0d0
|
||||
ZA_dyn(:,:) = 0d0
|
||||
|
||||
! Build dynamic A matrix
|
||||
|
||||
@ -63,7 +65,7 @@ subroutine dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,O
|
||||
chi = chi - rho2(i,j,kl)*rho2(a,b,kl)*Omega2(kl)/(Omega2(kl)**2 + eta**2)
|
||||
end do
|
||||
|
||||
A_dyn(ia,jb) = A_dyn(ia,jb) - 2d0*lambda*chi
|
||||
A_dyn(ia,jb) = A_dyn(ia,jb) - 1d0*lambda*chi
|
||||
|
||||
chi = 0d0
|
||||
|
||||
@ -77,7 +79,21 @@ subroutine dynamic_Tmatrix_A(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,O
|
||||
chi = chi + rho2(i,j,kl)*rho2(a,b,kl)*eps/(eps**2 + eta**2)
|
||||
end do
|
||||
|
||||
A_dyn(ia,jb) = A_dyn(ia,jb) + 2d0*lambda*chi
|
||||
A_dyn(ia,jb) = A_dyn(ia,jb) + 1d0*lambda*chi
|
||||
|
||||
chi = 0d0
|
||||
|
||||
do cd=1,nVV
|
||||
eps = + OmBSE - Omega1(cd) + (eGT(i) + eGT(j))
|
||||
chi = chi + rho1(i,j,cd)*rho1(a,b,cd)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
end do
|
||||
|
||||
do kl=1,nOO
|
||||
eps = + OmBSE + Omega2(kl) - (eGT(a) + eGT(b))
|
||||
chi = chi + rho2(i,j,kl)*rho2(a,b,kl)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
end do
|
||||
|
||||
ZA_dyn(ia,jb) = ZA_dyn(ia,jb) - 1d0*lambda*chi
|
||||
|
||||
end do
|
||||
end do
|
||||
|
@ -1,73 +0,0 @@
|
||||
subroutine dynamic_Tmatrix_ZA(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,eGT,Omega1,Omega2,rho1,rho2,OmBSE,ZA_dyn)
|
||||
|
||||
! Compute the dynamic part of the Bethe-Salpeter equation matrices
|
||||
|
||||
implicit none
|
||||
include 'parameters.h'
|
||||
|
||||
! Input variables
|
||||
|
||||
double precision,intent(in) :: eta
|
||||
integer,intent(in) :: nBas
|
||||
integer,intent(in) :: nC
|
||||
integer,intent(in) :: nO
|
||||
integer,intent(in) :: nV
|
||||
integer,intent(in) :: nR
|
||||
integer,intent(in) :: nS
|
||||
|
||||
integer,intent(in) :: nOO
|
||||
integer,intent(in) :: nVV
|
||||
|
||||
double precision,intent(in) :: lambda
|
||||
double precision,intent(in) :: eGT(nBas)
|
||||
double precision,intent(in) :: OmBSE
|
||||
|
||||
double precision,intent(in) :: Omega1(nVV)
|
||||
double precision,intent(in) :: Omega2(nOO)
|
||||
double precision,intent(in) :: rho1(nBas,nBas,nVV)
|
||||
double precision,intent(in) :: rho2(nBas,nBas,nOO)
|
||||
|
||||
! Local variables
|
||||
|
||||
double precision :: chi
|
||||
double precision :: eps
|
||||
integer :: i,j,a,b,ia,jb,cd,kl
|
||||
|
||||
! Output variables
|
||||
|
||||
double precision,intent(out) :: ZA_dyn(nS,nS)
|
||||
|
||||
! Initialization
|
||||
|
||||
ZA_dyn(:,:) = 0d0
|
||||
|
||||
! Build dynamic A matrix
|
||||
|
||||
ia = 0
|
||||
do i=nC+1,nO
|
||||
do a=nO+1,nBas-nR
|
||||
ia = ia + 1
|
||||
jb = 0
|
||||
do j=nC+1,nO
|
||||
do b=nO+1,nBas-nR
|
||||
jb = jb + 1
|
||||
|
||||
chi = 0d0
|
||||
do cd=1,nVV
|
||||
eps = + OmBSE - Omega1(cd) + (eGT(i) + eGT(j))
|
||||
chi = chi + rho1(i,j,cd)*rho1(a,b,cd)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
end do
|
||||
|
||||
do kl=1,nOO
|
||||
eps = + OmBSE + Omega2(kl) - (eGT(a) + eGT(b))
|
||||
chi = chi + rho2(i,j,kl)*rho2(a,b,kl)*(eps**2 - eta**2)/(eps**2 + eta**2)**2
|
||||
end do
|
||||
|
||||
ZA_dyn(ia,jb) = ZA_dyn(ia,jb) - 2d0*lambda*chi
|
||||
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
|
||||
end subroutine dynamic_Tmatrix_ZA
|
@ -26,7 +26,6 @@ subroutine static_Tmatrix_TA(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,ERI,Omega1,r
|
||||
! Local variables
|
||||
|
||||
double precision :: chi
|
||||
double precision :: eps
|
||||
integer :: i,j,a,b,ia,jb,kl,cd
|
||||
|
||||
! Output variables
|
||||
@ -45,18 +44,16 @@ subroutine static_Tmatrix_TA(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,ERI,Omega1,r
|
||||
chi = 0d0
|
||||
|
||||
do cd=1,nVV
|
||||
eps = Omega1(cd)**2 + eta**2
|
||||
! chi = chi + lambda*rho1(i,j,cd)*rho1(a,b,cd)*Omega1(cd)/eps
|
||||
chi = chi + rho1(i,j,cd)*rho1(a,b,cd)*Omega1(cd)/eps
|
||||
! chi = chi + lambda*rho1(i,j,cd)*rho1(a,b,cd)*Omega1(cd)/(Omega1(cd)**2 + eta**2)
|
||||
chi = chi + rho1(i,j,cd)*rho1(a,b,cd)*Omega1(cd)/(Omega1(cd)**2 + eta**2)
|
||||
enddo
|
||||
|
||||
do kl=1,nOO
|
||||
eps = Omega2(kl)**2 + eta**2
|
||||
! chi = chi - lambda*rho2(i,j,kl)*rho2(a,b,kl)*Omega2(kl)/eps
|
||||
chi = chi - rho2(i,j,kl)*rho2(a,b,kl)*Omega2(kl)/eps
|
||||
! chi = chi - lambda*rho2(i,j,kl)*rho2(a,b,kl)*Omega2(kl)/(Omega2(kl)**2 + eta**2)
|
||||
chi = chi - rho2(i,j,kl)*rho2(a,b,kl)*Omega2(kl)/(Omega2(kl)**2 + eta**2)
|
||||
enddo
|
||||
|
||||
TA(ia,jb) = TA(ia,jb) + 2d0*lambda*chi
|
||||
TA(ia,jb) = TA(ia,jb) + 1d0*lambda*chi
|
||||
|
||||
enddo
|
||||
enddo
|
||||
|
@ -26,7 +26,6 @@ subroutine static_Tmatrix_TB(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,ERI,Omega1,r
|
||||
! Local variables
|
||||
|
||||
double precision :: chi
|
||||
double precision :: eps
|
||||
integer :: i,j,a,b,ia,jb,kl,cd
|
||||
|
||||
! Output variables
|
||||
@ -45,18 +44,16 @@ subroutine static_Tmatrix_TB(eta,nBas,nC,nO,nV,nR,nS,nOO,nVV,lambda,ERI,Omega1,r
|
||||
chi = 0d0
|
||||
|
||||
do cd=1,nVV
|
||||
eps = Omega1(cd)**2 + eta**2
|
||||
! chi = chi + lambda*rho1(i,b,cd)*rho1(a,j,cd)*Omega1(cd)/eps
|
||||
chi = chi + rho1(i,b,cd)*rho1(a,j,cd)*Omega1(cd)/eps
|
||||
! chi = chi + lambda*rho1(i,b,cd)*rho1(a,j,cd)*Omega1(cd)/Omega1(cd)**2 + eta**2
|
||||
chi = chi + rho1(i,b,cd)*rho1(a,j,cd)*Omega1(cd)/Omega1(cd)**2 + eta**2
|
||||
enddo
|
||||
|
||||
do kl=1,nOO
|
||||
eps = Omega2(kl)**2 + eta**2
|
||||
! chi = chi - lambda*rho2(i,b,kl)*rho2(a,j,kl)*Omega2(kl)/eps
|
||||
chi = chi - rho2(i,b,kl)*rho2(a,j,kl)*Omega2(kl)/eps
|
||||
! chi = chi - lambda*rho2(i,b,kl)*rho2(a,j,kl)*Omega2(kl)/Omega2(kl)**2 + eta**2
|
||||
chi = chi - rho2(i,b,kl)*rho2(a,j,kl)*Omega2(kl)/Omega2(kl)**2 + eta**2
|
||||
enddo
|
||||
|
||||
TB(ia,jb) = TB(ia,jb) + 2d0*lambda*chi
|
||||
TB(ia,jb) = TB(ia,jb) + 1d0*lambda*chi
|
||||
|
||||
enddo
|
||||
enddo
|
||||
|
@ -10,7 +10,7 @@ program QuAcK
|
||||
logical :: doKS
|
||||
logical :: doMP2,doMP3,doMP2F12
|
||||
logical :: doCCD,doDCD,doCCSD,doCCSDT
|
||||
logical :: do_drCCD,do_rCCD,do_lCCD,do_pCCD
|
||||
logical :: do_drCCD,do_rCCD,do_lCCD,do_crCCD,do_pCCD
|
||||
logical :: doCIS,doCIS_D,doCID,doCISD,doFCI
|
||||
logical :: doRPA,doRPAx,doppRPA
|
||||
logical :: doADC
|
||||
@ -662,6 +662,27 @@ program QuAcK
|
||||
|
||||
end if
|
||||
|
||||
!------------------------------------------------------------------------
|
||||
! Perform crossed-ring CCD calculation
|
||||
!------------------------------------------------------------------------
|
||||
|
||||
do_crCCD = .false.
|
||||
|
||||
if(do_crCCD) then
|
||||
|
||||
call cpu_time(start_CCD)
|
||||
call ehRPA(TDA,doACFDT,exchange_kernel,singlet,triplet,0d0,nBas,nC,nO,nV,nR,nS,ENuc,ERHF,ERI_MO,dipole_int_MO,eHF)
|
||||
call crCCD(maxSCF_CC,thresh_CC,n_diis_CC,nBas,nC,nO,nV,nR, &
|
||||
ERI_MO,ENuc,ERHF,eHF)
|
||||
|
||||
call cpu_time(end_CCD)
|
||||
|
||||
t_CCD = end_CCD - start_CCD
|
||||
write(*,'(A65,1X,F9.3,A8)') 'Total CPU time for crossed-ring CCD = ',t_CCD,' seconds'
|
||||
write(*,*)
|
||||
|
||||
end if
|
||||
|
||||
!------------------------------------------------------------------------
|
||||
! Perform pair CCD calculation
|
||||
!------------------------------------------------------------------------
|
||||
|
130
src/RPA/ehRPA.f90
Normal file
130
src/RPA/ehRPA.f90
Normal file
@ -0,0 +1,130 @@
|
||||
subroutine ehRPA(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: eh channel |'
|
||||
write(*,*)'***********************************************************'
|
||||
write(*,*)
|
||||
|
||||
! TDA
|
||||
|
||||
if(TDA) then
|
||||
write(*,*) 'Tamm-Dancoff approximation activated!'
|
||||
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('ehRPA@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('ehRPA@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@ehRPA correlation energy (singlet) =',EcRPAx(1)
|
||||
write(*,'(2X,A50,F20.10)') 'Tr@ehRPA correlation energy (triplet) =',EcRPAx(2)
|
||||
write(*,'(2X,A50,F20.10)') 'Tr@ehRPA correlation energy =',EcRPAx(1) + EcRPAx(2)
|
||||
write(*,'(2X,A50,F20.10)') 'Tr@ehRPA 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 ehRPA 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 ehRPA
|
Loading…
Reference in New Issue
Block a user