UG0T0

input/methods

@@ -1,9 +1,9 @@
 # RHF UHF KS MOM 
-  T   F   F  F   
+  F   T   F  F   
 # MP2* MP3 MP2-F12
   F   F   F
 # CCD pCCD DCD CCSD CCSD(T) 
-  F   F    F   T    F
+  F   F    F   F    F
 # drCCD rCCD crCCD lCCD
   F     F    F     F
 # CIS* CIS(D) CID CISD FCI
@@ -13,7 +13,7 @@
 # G0F2* evGF2* qsGF2* G0F3 evGF3
   F     F      F      F    F
 # G0W0* evGW* qsGW* ufG0W0 ufGW
-  T     F     F     F      F
+  F     F     F     F      F
 # G0T0 evGT qsGT 
   T    F    F
 # MCMP2

input/options

@@ -15,6 +15,6 @@
 # ACFDT: AC Kx  XBS
          F  T   T
 # BSE: BSE dBSE dTDA evDyn
-        T    F    T    F
+        F    F    T    F
 # MCMP2: nMC    nEq    nWalk dt  nPrint iSeed doDrift
          1000000 100000 10    0.3 10000 1234  T

src/GT/UG0T0.f90

@@ -0,0 +1,301 @@
+subroutine UG0T0(doACFDT,exchange_kernel,doXBS,BSE,TDA_T,TDA,dBSE,dTDA,evDyn, &
+                 spin_conserved,spin_flip,linearize,eta,regularize,nBas,nC,nO,nV, &
+                 nR,nS,ENuc,EUHF,ERI,ERI_aaaa,ERI_aabb,ERI_bbbb, &
+                 dipole_int_aa,dipole_int_bb,PHF,cHF,eHF,Vxc,eG0T0)
+
+! Perform one-shot calculation with a T-matrix self-energy (G0T0)
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  logical,intent(in)            :: doACFDT
+  logical,intent(in)            :: exchange_kernel
+  logical,intent(in)            :: doXBS
+  logical,intent(in)            :: BSE
+  logical,intent(in)            :: TDA_T
+  logical,intent(in)            :: TDA
+  logical,intent(in)            :: dBSE
+  logical,intent(in)            :: dTDA
+  logical,intent(in)            :: evDyn
+  logical,intent(in)            :: spin_conserved
+  logical,intent(in)            :: spin_flip
+  logical,intent(in)            :: linearize
+  double precision,intent(in)   :: eta
+  logical,intent(in)            :: regularize
+
+  integer,intent(in)            :: nBas
+  integer,intent(in)            :: nC(nspin) 
+  integer,intent(in)            :: nO(nspin)
+  integer,intent(in)            :: nV(nspin)
+  integer,intent(in)            :: nR(nspin)
+  integer,intent(in)            :: nS(nspin)
+  double precision,intent(in)   :: ENuc
+  double precision,intent(in)   :: EUHF
+  double precision,intent(in)   :: Vxc(nBas,nspin)
+  double precision,intent(in)   :: eHF(nBas,nspin)
+  double precision,intent(in)   :: cHF(nBas,nBas,nspin)
+  double precision,intent(in)   :: PHF(nBas,nBas,nspin)
+  double precision,intent(in)   :: ERI(nBas,nBas,nBas,nBas) 
+  double precision,intent(in)   :: ERI_aaaa(nBas,nBas,nBas,nBas)
+  double precision,intent(in)   :: ERI_aabb(nBas,nBas,nBas,nBas)
+  double precision,intent(in)   :: ERI_bbbb(nBas,nBas,nBas,nBas)
+  double precision,intent(in)   :: dipole_int_aa(nBas,nBas,ncart)
+  double precision,intent(in)   :: dipole_int_bb(nBas,nBas,ncart)
+
+! Local variables
+
+  integer                       :: ispin,is
+  integer                       :: iblock 
+  integer                       :: nH_sc,nH_sf,nHaa,nHab,nHbb
+  integer                       :: nP_sc,nP_sf,nPaa,nPab,nPbb
+  double precision              :: EcRPA(nspin),Ecaa,Ecbb
+  double precision              :: EcBSE(nspin)
+  double precision              :: EcAC(nspin)
+  double precision              :: EcGM
+  double precision,allocatable  :: Omega1ab(:),Omega1aa(:),Omega1bb(:)
+  double precision,allocatable  :: X1ab(:,:),X1aa(:,:),X1bb(:,:)
+  double precision,allocatable  :: Y1ab(:,:),Y1aa(:,:),Y1bb(:,:)
+  double precision,allocatable  :: rho1ab(:,:,:),rho1aa(:,:,:),rho1bb(:,:,:)
+  double precision,allocatable  :: Omega2ab(:),Omega2aa(:),Omega2bb(:)
+  double precision,allocatable  :: X2ab(:,:),X2aa(:,:),X2bb(:,:)
+  double precision,allocatable  :: Y2ab(:,:),Y2aa(:,:),Y2bb(:,:)
+  double precision,allocatable  :: rho2ab(:,:,:),rho2aa(:,:,:),rho2bb(:,:,:)
+  double precision,allocatable  :: SigX(:,:)
+  double precision,allocatable  :: SigT(:,:)
+  double precision,allocatable  :: Z(:,:)
+
+! Output variables
+
+  double precision,intent(out)  :: eG0T0(nBas,nspin)
+
+! Hello world
+
+  write(*,*)
+  write(*,*)'************************************************'
+  write(*,*)'|          One-shot G0T0 calculation           |'
+  write(*,*)'|         *** Unrestricted version ***         |'
+  write(*,*)'************************************************'
+  write(*,*)
+
+! Dimensions of the pp-URPA linear reponse matrices
+
+  nPaa = nV(1)*(nV(1)-1)/2
+  nPbb = nV(2)*(nV(2)-1)/2
+
+  nHaa = nO(1)*(nO(1)-1)/2;
+  nHbb = nO(2)*(nO(2)-1)/2;
+
+  nPab = nV(1)*nV(2)
+  nHab = nO(1)*nO(2)
+
+  nP_sc = nPab
+  nH_sc = nHab
+
+  nP_sf = nPaa + nPbb
+  nH_sf = nHaa + nHbb
+  
+
+! Memory allocation
+
+  allocate(Omega1ab(nPab),X1ab(nPab,nPab),Y1ab(nHab,nPab), & 
+           Omega2ab(nHab),X2ab(nPab,nHab),Y2ab(nHab,nHab), & 
+           rho1ab(nBas,nBas,nPab),rho2ab(nBas,nBas,nHab), & 
+           Omega1aa(nPaa),X1aa(nPaa,nPaa),Y1aa(nHaa,nPaa), & 
+           Omega2aa(nHaa),X2aa(nPaa,nHaa),Y2aa(nHaa,nHaa), & 
+           rho1aa(nBas,nBas,nPaa),rho2aa(nBas,nBas,nHaa), & 
+           Omega1bb(nPbb),X1bb(nPbb,nPbb),Y1bb(nHbb,nPbb), &
+           rho1bb(nBas,nBas,nPbb),rho2bb(nBas,nBas,nHbb), &
+           SigX(nBas,nspin),SigT(nBas,nspin),Z(nBas,nspin))
+
+!----------------------------------------------
+! alpha-beta block
+!----------------------------------------------
+
+  ispin  = 1
+  iblock = 1
+! iblock = 1
+
+! Compute linear response
+
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sc,nHaa,nHab,nHbb,nH_sc,1d0,eHF,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1ab,X1ab,Y1ab, &
+                                       Omega2ab,X2ab,Y2ab,EcRPA(ispin)) 
+
+! EcRPA(ispin) = 1d0*EcRPA(ispin)
+
+  call print_excitation('pp-RPA (N+2)',iblock,nPab,Omega1ab(:))
+  call print_excitation('pp-RPA (N-2)',iblock,nHab,Omega2ab(:))
+
+!----------------------------------------------
+! alpha-alpha block
+!----------------------------------------------
+
+  ispin  = 2
+  iblock = 2 
+
+! Compute linear response
+
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sf,nHaa,nHab,nHbb,nH_sc,1d0,eHF,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1aa,X1aa,Y1aa, &
+                                       Omega2aa,X2aa,Y2aa,EcRPA(ispin))  
+ 
+
+! EcRPA(ispin) = 2d0*EcRPA(ispin)
+! EcRPA(ispin) = 3d0*EcRPA(ispin)
+
+  call print_excitation('pp-RPA (N+2)',iblock,nPaa,Omega1aa(:))
+  call print_excitation('pp-RPA (N-2)',iblock,nHaa,Omega2aa(:))
+
+!----------------------------------------------
+! beta-beta block
+!----------------------------------------------
+
+  ispin  = 2
+  iblock = 3
+
+! Compute linear response
+
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sc,nHaa,nHab,nHbb,nH_sf,1d0,eHF,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1bb,X1bb,Y1bb, &
+                                       Omega2bb,X2bb,Y2bb,EcRPA(ispin))
+
+
+! EcRPA(ispin) = 2d0*EcRPA(ispin)
+! EcRPA(ispin) = 3d0*EcRPA(ispin)
+
+  call print_excitation('pp-RPA (N+2)',iblock,nPbb,Omega1bb(:))
+  call print_excitation('pp-RPA (N-2)',iblock,nHbb,Omega2bb(:))
+
+!----------------------------------------------
+! Compute T-matrix version of the self-energy 
+!----------------------------------------------
+
+  EcGM    = 0d0
+  SigT(:,:) = 0d0
+  Z(:,:)    = 0d0
+
+!alpha-beta block
+  ispin = 1 
+  iblock = 1 
+
+  call unrestricted_excitation_density_Tmatrix(iblock,nBas,nC,nO,nV,nR,nHab,nPab, &
+                                               ERI_aaaa,ERI_aabb,ERI_bbbb,X1ab,Y1ab, &
+                                               rho1ab,X2ab,Y2ab,rho2ab)
+
+  call unrestricted_self_energy_Tmatrix_diag(ispin,eta,nBas,nC,nO,nV,nR,nHab,nPab,eHF, &
+                                             Omega1ab,rho1ab,Omega2ab,rho2ab,EcGM,SigT) 
+
+  call unrestricted_renormalization_factor_Tmatrix(eta,nBas,nC,nO,nV,nR,nHab,nPab,eHF, &
+                                                   Omega1ab,rho1ab,Omega2ab,rho2ab,Z) 
+!alpha-alpha block
+  ispin = 2 
+  iblock = 2 
+
+  call unrestricted_excitation_density_Tmatrix(iblock,nBas,nC,nO,nV,nR,nHaa,nPaa, &
+                                               ERI_aaaa,ERI_aabb,ERI_bbbb,X1aa,Y1aa, &
+                                               rho1aa,X2aa,Y2aa,rho2aa)
+
+  call unrestricted_self_energy_Tmatrix_diag(ispin,eta,nBas,nC,nO,nV,nR,nHaa,nPaa,eHF, &
+                                             Omega1aa,rho1aa,Omega2aa,rho2aa,EcGM,SigT)
+
+  call unrestricted_renormalization_factor_Tmatrix(eta,nBas,nC,nO,nV,nR,nHaa,nPaa,eHF, &
+                                                   Omega1aa,rho1aa,Omega2aa,rho2aa,Z)
+!beta-beta block
+  ispin = 2 
+  iblock = 3 
+
+  call unrestricted_excitation_density_Tmatrix(iblock,nBas,nC,nO,nV,nR,nHbb,nPbb, &
+                                               ERI_aaaa,ERI_aabb,ERI_bbbb,X1bb,Y1bb, &
+                                               rho1bb,X2bb,Y2bb,rho2bb)
+
+  call unrestricted_self_energy_Tmatrix_diag(ispin,eta,nBas,nC,nO,nV,nR,nHbb,nPbb,eHF, &
+                                             Omega1bb,rho1bb,Omega2bb,rho2bb,EcGM,SigT)
+
+  call unrestricted_renormalization_factor_Tmatrix(eta,nBas,nC,nO,nV,nR,nHbb,nPbb,eHF, &
+                                                   Omega1bb,rho1bb,Omega2bb,rho2bb,Z)  
+
+
+  Z(:,:) = 1d0/(1d0 - Z(:,:))
+
+!----------------------------------------------
+! Compute the exchange part of the self-energy
+!----------------------------------------------
+  
+  do is=1,nspin
+    call self_energy_exchange_diag(nBas,cHF(:,:,is),PHF(:,:,is),ERI,SigX(:,is))
+  end do 
+
+!----------------------------------------------
+! Solve the quasi-particle equation
+!----------------------------------------------
+
+  if(linearize) then
+
+!   eG0T0(:) = eHF(:) + Z(:)*SigT(:)
+    eG0T0(:,:) = eHF(:,:) + Z(:,:)*(SigX(:,:) + SigT(:,:) - Vxc(:,:))
+
+!    call matout(nBas,1,SigX)
+!    call matout(nBas,1,Vxc)
+
+  else
+  
+    eG0T0(:,:) = eHF(:,:) + SigX(:,:) + SigT(:,:) - Vxc(:,:)
+
+  end if
+
+!----------------------------------------------
+! Dump results
+!----------------------------------------------
+
+! Compute the ppRPA correlation energy
+
+!alpha-beta block
+
+  ispin  = 1
+  iblock = 1
+
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sc,nHaa,nHab,nHbb,nH_sc,1d0,eG0T0,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1ab,X1ab,Y1ab, &
+                                       Omega2ab,X2ab,Y2ab,EcRPA(ispin))
+
+!alpha-alpha block
+ 
+  ispin  = 2
+  iblock = 2
+  
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sc,nHaa,nHab,nHbb,nH_sc,1d0,eG0T0,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1aa,X1aa,Y1aa, &
+                                       Omega2aa,X2aa,Y2aa,EcRPA(ispin)) 
+ 
+  Ecaa = EcRPA(2)
+
+!beta-beta block
+ 
+  iblock = 3
+  
+  call unrestricted_linear_response_pp(iblock,TDA,nBas,nC,nO,nV,nR,nPaa,nPab,nPbb, &
+                                       nP_sc,nHaa,nHab,nHbb,nH_sc,1d0,eG0T0,ERI_aaaa, &
+                                       ERI_aabb,ERI_bbbb,Omega1bb,X1bb,Y1bb, &
+                                       Omega2bb,X2bb,Y2bb,EcRPA(ispin))
+  
+  Ecbb = EcRPA(2) 
+  EcRPA(2) = Ecaa + Ecbb
+  EcRPA(1) = EcRPA(1) - EcRPA(2)
+  EcRPA(2) = 3d0*EcRPA(2)
+
+!  call print_G0T0(nBas,nO,eHF,ENuc,ERHF,SigT,Z,eG0T0,EcGM,EcRPA)
+
+! Free memory
+
+  deallocate(Omega1ab,X1ab,Y1ab,Omega2ab,X2ab,Y2ab,rho1ab,rho2ab, &
+             Omega1aa,X1aa,Y1aa,Omega2aa,X2aa,Y2aa,rho1aa,rho2aa, &
+             Omega1bb,X1bb,Y1bb,Omega2bb,X2bb,Y2bb,rho1bb,rho2bb)
+
+end subroutine UG0T0

src/GT/unrestricted_excitation_density_Tmatrix.f90

@@ -0,0 +1,222 @@
+subroutine unrestricted_excitation_density_Tmatrix(ispin,nBas,nC,nO,nV,nR,nH,nP,ERI_aaaa,ERI_aabb,ERI_bbbb,X1,Y1,rho1,X2,Y2,rho2)
+
+! Compute excitation densities for T-matrix self-energy
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  integer,intent(in)            :: ispin
+  integer,intent(in)            :: nBas
+  integer,intent(in)            :: nC(nspin)
+  integer,intent(in)            :: nO(nspin)
+  integer,intent(in)            :: nV(nspin)
+  integer,intent(in)            :: nR(nspin)
+  double precision,intent(in)   :: ERI_aaaa(nBas,nBas,nBas,nBas)
+  double precision,intent(in)   :: ERI_aabb(nBas,nBas,nBas,nBas)
+  double precision,intent(in)   :: ERI_bbbb(nBas,nBas,nBas,nBas)
+  integer,intent(in)            :: nH
+  integer,intent(in)            :: nP 
+  double precision,intent(in)   :: X1(nP,nP)
+  double precision,intent(in)   :: Y1(nH,nP)
+  double precision,intent(in)   :: X2(nP,nH)
+  double precision,intent(in)   :: Y2(nH,nH)
+
+! Local variables
+
+  integer                       :: i,j,k,l
+  integer                       :: a,b,c,d
+  integer                       :: p,q
+  integer                       :: ab,cd,ij,kl
+  double precision,external     :: Kronecker_delta
+
+! Output variables
+
+  double precision,intent(out)  :: rho1(nBas,nBas,nP)
+  double precision,intent(out)  :: rho2(nBas,nBas,nH)
+
+! Initialization
+
+  rho1(:,:,:) = 0d0
+  rho2(:,:,:) = 0d0
+
+!----------------------------------------------
+! alpha-beta block
+!----------------------------------------------
+
+  if(ispin == 1) then
+
+    do p=nC(1)+1,nBas-nR(1)
+      do q=nC(2)+1,nBas-nR(2)
+        do ab=1,nP 
+        cd = 0
+          do c=nO(1)+1,nBas-nR(1)
+            do d=nO(2),nBas-nR(1)
+              cd = cd + 1
+
+              rho1(p,q,ab) = rho1(p,q,ab) & 
+              + (1d0*ERI_aabb(p,q,c,d) + 0d0*ERI_aabb(p,q,d,c))*X1(cd,ab)
+
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(1)+1,nO(1)
+            do l=nC(1)+1,nO(1)
+              kl = kl + 1
+
+              rho1(p,q,ab) = rho1(p,q,ab) & 
+              + (1d0*ERI_aabb(p,q,k,l) + 0d0*ERI_aabb(p,q,l,k))*Y1(kl,ab)
+
+            end do
+          end do
+        end do
+        
+ 
+        ij = 0
+        do i=nC(1)+1,nO(1)
+          do j=nC(2)+1,nO(2)
+            ij = ij + 1
+ 
+          cd = 0
+          do c=nO(1)+1,nBas-nR(1)
+            do d=nO(2)+1,nBas-nR(2)
+              cd = cd + 1
+              rho2(p,q,ij) = rho2(p,q,ij) &
+              + (1d0*ERI_aabb(p,q,c,d) + 0d0*ERI_aabb(p,q,d,c))*X2(cd,ij)
+
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(1)+1,nO(1)
+            do l=nC(1)+1,nO(1)
+              kl = kl + 1
+              rho2(p,q,ij) = rho2(p,q,ij) &
+              + (1d0*ERI_aabb(p,q,k,l) + 0d0*ERI_aabb(p,q,l,k))*Y2(kl,ij)
+
+            end do
+          end do
+ 
+        end do
+        end do
+
+      end do
+    end do
+
+  end if
+
+!----------------------------------------------
+! alpha-alpha block 
+!----------------------------------------------
+
+  if(ispin == 2) then
+
+    do p=nC(1)+1,nBas-nR(1)
+      do q=nC(1)+1,nBas-nR(1)
+ 
+        do ab=1,nP
+ 
+          cd = 0
+          do c=nO(1)+1,nBas-nR(1)
+            do d=c+1,nBas-nR(1)
+              cd = cd + 1
+              rho1(p,q,ab) = rho1(p,q,ab) & 
+                           + (ERI_aaaa(p,q,c,d) - ERI_aaaa(p,q,d,c))*X1(cd,ab) 
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(1)+1,nO(1)
+            do l=k+1,nO(1)
+              kl = kl + 1
+              rho1(p,q,ab) = rho1(p,q,ab) & 
+                           + (ERI_aaaa(p,q,k,l) - ERI_aaaa(p,q,l,k))*Y1(kl,ab) 
+            end do
+          end do
+ 
+        end do
+ 
+        do ij=1,nH
+ 
+          cd = 0
+          do c=nO(1)+1,nBas-nR(1)
+            do d=c+1,nBas-nR(1)
+              cd = cd + 1
+              rho2(p,q,ij) = rho2(p,q,ij) & 
+                           + (ERI_aaaa(p,q,c,d) - ERI_aaaa(p,q,d,c))*X2(cd,ij) 
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(1)+1,nO(1)
+            do l=k+1,nO(1)
+              kl = kl + 1
+              rho2(p,q,ij) = rho2(p,q,ij) & 
+                           + (ERI_aaaa(p,q,k,l) - ERI_aaaa(p,q,l,k))*Y2(kl,ij) 
+            end do
+          end do
+ 
+        end do
+
+      end do
+    end do
+
+  end if
+
+!----------------------------------------------
+! beta-beta block
+!----------------------------------------------
+
+  if(ispin == 3) then
+
+    do p=nC(2)+1,nBas-nR(2)
+      do q=nC(2)+1,nBas-nR(2)
+ 
+        do ab=1,nP
+ 
+          cd = 0
+          do c=nO(2)+1,nBas-nR(2)
+            do d=c+1,nBas-nR(2)
+              cd = cd + 1
+              rho1(p,q,ab) = rho1(p,q,ab) + (ERI_bbbb(p,q,c,d)-ERI_bbbb(p,q,d,c))*X1(cd,ab) 
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(2)+1,nO(2)
+            do l=k+1,nO(2)
+              kl = kl + 1
+              rho1(p,q,ab) = rho1(p,q,ab) + (ERI_bbbb(p,q,k,l)-ERI_bbbb(p,q,l,k))*Y1(kl,ab) 
+            end do
+          end do
+ 
+        end do
+ 
+        do ij=1,nH
+ 
+          cd = 0
+          do c=nO(2)+1,nBas-nR(2)
+            do d=c+1,nBas-nR(2)
+              cd = cd + 1
+              rho2(p,q,ij) = rho2(p,q,ij) + (ERI_bbbb(p,q,c,d)-ERI_bbbb(p,q,d,c))*X2(cd,ij) 
+            end do
+          end do
+ 
+          kl = 0
+          do k=nC(2)+1,nO(2)
+            do l=k+1,nO(2)
+              kl = kl + 1
+              rho2(p,q,ij) = rho2(p,q,ij) + (ERI_bbbb(p,q,k,l)-ERI_bbbb(p,q,l,k))*Y2(kl,ij) 
+            end do
+          end do
+ 
+        end do
+
+      end do
+    end do
+
+  end if
+
+end subroutine unrestricted_excitation_density_Tmatrix

src/GT/unrestricted_renormalization_factor_Tmatrix.f90

@@ -0,0 +1,81 @@
+subroutine unrestricted_renormalization_factor_Tmatrix(ispin,eta,nBas,nC,nO,nV,nR,nH,nP,e,Omega1,rho1,Omega2,rho2,Z)
+
+! Compute renormalization factor of the T-matrix self-energy
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  double precision,intent(in)   :: eta
+  integer,intent(in)            :: nBas,nC(nspin),nO(nspin),nV(nspin),nR(nspin)
+  integer,intent(in)            :: nH,ispin
+  integer,intent(in)            :: nP
+  double precision,intent(in)   :: e(nBas,nspin)
+  double precision,intent(in)   :: Omega1(nP)
+  double precision,intent(in)   :: rho1(nBas,nBas,nP,nspin)
+  double precision,intent(in)   :: Omega2(nH)
+  double precision,intent(in)   :: rho2(nBas,nBas,nH,nspin)
+
+! Local variables
+
+  integer                       :: i,a,p,cd,kl
+  double precision              :: eps
+
+! Output variables
+
+  double precision,intent(out)  :: Z(nBas,nspin)
+
+! Occupied part of the T-matrix self-energy 
+  
+  if(ispin==1) then
+
+    do p=nC(1)+1,nBas-nR(1)
+      do i=nC(1)+1,nO(1)
+        do cd=1,nP
+          eps  = e(p,1) + e(i,1) - Omega1(cd)
+          Z(p,1) = Z(p,1) - rho1(p,i,cd,1)**2*(eps/(eps**2 + eta**2))**2
+        enddo
+      enddo
+    enddo 
+
+! Virtual part of the T-matrix self-energy
+
+    do p=nC(1)+1,nBas-nR(1)
+      do a=nO(1)+1,nBas-nR(1)
+        do kl=1,nH
+          eps  = e(p,1) + e(a,1) - Omega2(kl)
+          Z(p,1) = Z(p,1) - rho2(p,a,kl,1)**2*(eps/(eps**2 + eta**2))**2
+        enddo
+      enddo
+    enddo
+
+  end if
+
+! Occupied part of the T-matrix self-energy 
+ 
+  if(ispin==2) then
+
+    do p=nC(2)+1,nBas-nR(2)
+      do i=nC(2)+1,nO(2)
+        do cd=1,nP
+          eps  = e(p,2) + e(i,2) - Omega1(cd)
+          Z(p,2) = Z(p,2) - rho1(p,i,cd,2)**2*(eps/(eps**2 + eta**2))**2
+        enddo
+      enddo
+    enddo
+
+! Virtual part of the T-matrix self-energy
+
+    do p=nC(2)+1,nBas-nR(2)
+      do a=nO(2)+1,nBas-nR(2)
+        do kl=1,nH
+          eps  = e(p,2) + e(a,2) - Omega2(kl)
+          Z(p,2) = Z(p,2) - rho2(p,a,kl,2)**2*(eps/(eps**2 + eta**2))**2
+        enddo
+      enddo
+    enddo
+
+  end if
+
+end subroutine unrestricted_renormalization_factor_Tmatrix

src/GT/unrestricted_self_energy_Tmatrix_diag.f90

@@ -0,0 +1,147 @@
+subroutine unrestricted_self_energy_Tmatrix_diag(ispin,eta,nBas,nC,nO,nV,nR,nH,nP,e,Omega1,rho1,Omega2,rho2,EcGM,SigT)
+
+! Compute diagonal of the correlation part of the T-matrix self-energy
+
+  implicit none
+  include 'parameters.h'
+
+! Input variables
+
+  double precision,intent(in)   :: eta
+  integer,intent(in)            :: nBas
+  integer,intent(in)            :: nC(nspin)
+  integer,intent(in)            :: nO(nspin)
+  integer,intent(in)            :: nV(nspin)
+  integer,intent(in)            :: nR(nspin)
+  integer,intent(in)            :: nH,ispin
+  integer,intent(in)            :: nP
+  double precision,intent(in)   :: e(nBas,nspin)
+  double precision,intent(in)   :: Omega1(nP)
+  double precision,intent(in)   :: rho1(nBas,nBas,nP,nspin)
+  double precision,intent(in)   :: Omega2(nH)
+  double precision,intent(in)   :: rho2(nBas,nBas,nH,nspin)
+
+! Local variables
+
+  integer                       :: i,j,a,b,p,cd,kl
+  double precision              :: eps
+
+! Output variables
+
+  double precision,intent(inout)  :: EcGM(nspin)
+  double precision,intent(inout)  :: SigT(nBas,nspin)
+
+!----------------------------------------------
+! Occupied part of the T-matrix self-energy 
+!----------------------------------------------
+
+  if(ispin==1) then 
+
+    do p=nC(1)+1,nBas-nR(1)
+      do i=nC(1)+1,nO(1)
+        do cd=1,nP
+          eps = e(p,1) + e(i,1) - Omega1(cd)
+          SigT(p,1) = SigT(p,1) + rho1(p,i,cd,1)**2*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+  end if  
+ 
+!beta part
+  
+  if(ispin==2) then 
+
+    do p=nC(2)+1,nBas-nR(2)
+      do i=nC(2)+1,nO(2)
+        do cd=1,nP
+          eps = e(p,2) + e(i,2) - Omega1(cd)
+          SigT(p,2) = SigT(p,2) + rho1(p,i,cd,2)**2*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+  end if 
+  
+!----------------------------------------------
+! Virtual part of the T-matrix self-energy
+!----------------------------------------------
+  
+  !alpha part 
+  
+  if(ispin==1) then
+
+    do p=nC(1)+1,nBas-nR(1)
+      do a=nO(1)+1,nBas-nR(1)
+        do kl=1,nH
+          eps = e(p,1) + e(a,1) - Omega2(kl)
+          SigT(p,1) = SigT(p,1) + rho2(p,a,kl,1)**2*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+  
+  end if
+
+  !alpha part 
+
+  if(ispin==2) then
+
+    do p=nC(2)+1,nBas-nR(2)
+      do a=nO(2)+1,nBas-nR(2)
+        do kl=1,nH
+          eps = e(p,2) + e(a,2) - Omega2(kl)
+          SigT(p,2) = SigT(p,2) + rho2(p,a,kl,2)**2*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+  end if 
+
+!----------------------------------------------
+! Galitskii-Migdal correlation energy
+!----------------------------------------------
+  if(ispin==1) then
+
+    do i=nC(1)+1,nO(1)
+      do j=nC(1)+1,nO(1)
+        do cd=1,nP
+          eps = e(i,1) + e(j,1) - Omega1(cd)
+          EcGM(1) = EcGM(1) + rho1(i,j,cd,1)*rho1(i,j,cd,1)*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo 
+
+    do a=nO(1)+1,nBas-nR(1)
+      do b=nO(1)+1,nBas-nR(1)
+        do kl=1,nH
+          eps = e(a,1) + e(b,1) - Omega2(kl)
+          EcGM(1) = EcGM(1) - rho2(a,b,kl,1)*rho2(a,b,kl,1)*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+  end if
+
+  if(ispin==2) then
+
+    do i=nC(2)+1,nO(2)
+      do j=nC(2)+1,nO(2)
+        do cd=1,nP
+          eps = e(i,2) + e(j,2) - Omega1(cd)
+          EcGM(2) = EcGM(2) + rho1(i,j,cd,2)*rho1(i,j,cd,2)*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+    do a=nO(2)+1,nBas-nR(2)
+      do b=nO(2)+1,nBas-nR(2)
+        do kl=1,nH
+          eps = e(a,2) + e(b,2) - Omega2(kl)
+          EcGM(2) = EcGM(2) - rho2(a,b,kl,2)*rho2(a,b,kl,2)*eps/(eps**2 + eta**2)
+        enddo
+      enddo
+    enddo
+
+  end if
+
+end subroutine unrestricted_self_energy_Tmatrix_diag

src/QuAcK/QuAcK.f90

@@ -1155,7 +1155,11 @@ program QuAcK
 
     if(unrestricted) then 
 
-      print*,'!!! G0T0 NYI at the unrestricted level !!!'
+      !print*,'!!! G0T0 NYI at the unrestricted level !!!'
+       call UG0T0(doACFDT,exchange_kernel,doXBS,BSE,TDA_T,TDA,dBSE,dTDA,evDyn, &
+                 spin_conserved,spin_flip,linGT,eta_GT,regGT,nBas,nC,nO,nV, &
+                 nR,nS,ENuc,EUHF,ERI_AO,ERI_MO_aaaa,ERI_MO_aabb,ERI_MO_bbbb, &
+                 dipole_int_aa,dipole_int_bb,PHF,cHF,eHF,Vxc,eG0T0)
 
     else