clean up

input/basis

@@ -1,25 +1,9 @@
-1  10
+1   3
-S   4
+S   3
-  1    528.5000000              0.0009400        
+  1     38.3600000              0.0238090        
-  2     79.3100000              0.0072140        
+  2      5.7700000              0.1548910        
-  3     18.0500000              0.0359750        
+  3      1.2400000              0.4699870        
-  4      5.0850000              0.1277820        
 S   1
-  1      1.6090000              1.0000000        
+  1      0.2976000              1.0000000        
-S   1
-  1      0.5363000              1.0000000        
-S   1
-  1      0.1833000              1.0000000        
 P   1
-  1      5.9940000              1.0000000        
+  1      1.2750000              1.0000000
-P   1
-  1      1.7450000              1.0000000        
-P   1
-  1      0.5600000              1.0000000        
-D   1
-  1      4.2990000              1.0000000        
-D   1
-  1      1.2230000              1.0000000        
-F   1
-  1      2.6800000              1.0000000
-

input/weight

@@ -1,25 +1,9 @@
-1  10
+1   3
-S   4
+S   3
-  1    528.5000000              0.0009400        
+  1     38.3600000              0.0238090        
-  2     79.3100000              0.0072140        
+  2      5.7700000              0.1548910        
-  3     18.0500000              0.0359750        
+  3      1.2400000              0.4699870        
-  4      5.0850000              0.1277820        
 S   1
-  1      1.6090000              1.0000000        
+  1      0.2976000              1.0000000        
-S   1
-  1      0.5363000              1.0000000        
-S   1
-  1      0.1833000              1.0000000        
 P   1
-  1      5.9940000              1.0000000        
+  1      1.2750000              1.0000000
-P   1
-  1      1.7450000              1.0000000        
-P   1
-  1      0.5600000              1.0000000        
-D   1
-  1      4.2990000              1.0000000        
-D   1
-  1      1.2230000              1.0000000        
-F   1
-  1      2.6800000              1.0000000
-

src/eDFT/RB88_gga_exchange_individual_energy.f90

@@ -40,7 +40,7 @@ subroutine RB88_gga_exchange_individual_energy(nGrid,weight,rhow,drhow,rho,drho,
     r  = max(0d0,0.5d0*rhow(iG))
     rI = max(0d0,0.5d0*rho(iG))
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       g = 0.25d0*(drho(1,iG)**2 + drho(2,iG)**2 + drho(3,iG)**2)
       x = sqrt(g)/r**(4d0/3d0)

src/eDFT/RCC_lda_exchange_individual_energy.f90

@@ -83,7 +83,7 @@ subroutine RCC_lda_exchange_individual_energy(nEns,wEns,aCC_w1,aCC_w2,nGrid,weig
     r  = max(0d0,rhow(iG))
     rI = max(0d0,rho(iG))
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       e_p  =         Cx*r**(1d0/3d0)
       dedr = 1d0/3d0*Cx*r**(-2d0/3d0)

src/eDFT/RMFL20_lda_exchange_individual_energy.f90

@@ -42,7 +42,7 @@ subroutine RMFL20_lda_exchange_individual_energy(LDA_centered,nEns,wEns,nGrid,we
     r  = max(0d0,rhow(iG))
     rI = max(0d0,rho(iG))
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       e_p  =         Cxw*r**(1d0/3d0)
       dedr = 1d0/3d0*Cxw*r**(-2d0/3d0)

src/eDFT/RVWN5_lda_correlation_individual_energy.f90

@@ -42,7 +42,7 @@ subroutine RVWN5_lda_correlation_individual_energy(nGrid,weight,rhow,rho,Ec)
     r = max(0d0,rhow(iG))
     rI = max(0d0,rho(iG))
    
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
    
       rs = (4d0*pi*r/3d0)**(-1d0/3d0)
       x = sqrt(rs)

src/eDFT/US51_lda_exchange_energy.f90

@@ -1,4 +1,4 @@
-subroutine US51_lda_exchange_energy(nGrid,weight,rho,Ex,wEns,nEns)
+subroutine US51_lda_exchange_energy(nGrid,weight,rho,Ex)
 
 ! Compute Slater's LDA exchange energy
 
@@ -11,9 +11,6 @@ subroutine US51_lda_exchange_energy(nGrid,weight,rho,Ex,wEns,nEns)
   double precision,intent(in)   :: weight(nGrid)
   double precision,intent(in)   :: rho(nGrid)
 
-  integer,intent(in)            :: nEns
-  double precision,intent(in)   :: wEns(nEns)
-
 ! Local variables
 
   integer                       :: iG

src/eDFT/US51_lda_exchange_individual_energy.f90

@@ -32,12 +32,18 @@ subroutine US51_lda_exchange_individual_energy(nGrid,weight,rhow,rho,Ex)
     r  = max(0d0,rhow(iG))
     rI = max(0d0,rho(iG))
 
-    if(r > threshold .or. rI > threshold) then
+    if(r > threshold) then
 
       e    =         alpha*r**(1d0/3d0)
       dedr = 1d0/3d0*alpha*r**(-2d0/3d0)
 
-      Ex = Ex + weight(iG)*(e*rI + dedr*r*rI - dedr*r*r)
+      Ex = Ex - weight(iG)*dedr*r*r
+
+      if(rI > threshold) then
+
+      Ex = Ex + weight(iG)*(e*rI + dedr*r*rI)
+
+      endif
 
     endif
 

src/eDFT/UVWN5_lda_correlation_energy.f90

@@ -73,7 +73,7 @@ subroutine UVWN5_lda_correlation_energy(nGrid,weight,rho,Ec)
 
 !   alpha-beta contribution
 
-    if(ra > threshold .and. rb > threshold) then
+    if(ra > threshold .or. rb > threshold) then
 
       r = ra + rb
       rs = (4d0*pi*r/3d0)**(-1d0/3d0)

src/eDFT/UW38_lda_correlation_energy.f90

@@ -35,7 +35,7 @@ subroutine UW38_lda_correlation_energy(nGrid,weight,rho,Ec)
     ra = max(0d0,rho(iG,1))
     rb = max(0d0,rho(iG,2))
 
-    if(ra > threshold .and. rb > threshold) then
+    if(ra > threshold .or. rb > threshold) then
 
       r = ra + rb
 

src/eDFT/UW38_lda_correlation_individual_energy.f90

@@ -45,7 +45,7 @@ subroutine UW38_lda_correlation_individual_energy(nGrid,weight,rhow,rho,Ec)
     r  = ra + rb
     rI = raI + rbI
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       epsc  = ra*rb/(r + d*r**(2d0/3d0))
       dFcdra = epsc*(d/(3d0*r**(4d0/3d0)*(1d0 + d*r**(-1d0/3d0))) - 1d0/r + 1d0/ra)

src/eDFT/UWN5_lda_correlation_individual_energy.f90

@@ -1,204 +0,0 @@
-subroutine UVWN5_lda_correlation_individual_energy(nGrid,weight,rhow,rho,Ec)
-
-! Compute VWN5 LDA correlation potential
-
-  implicit none
-
-  include 'parameters.h'
-
-! Input variables
-
-  integer,intent(in)            :: nGrid
-  double precision,intent(in)   :: weight(nGrid)
-  double precision,intent(in)   :: rhow(nGrid,nspin)
-  double precision,intent(in)   :: rho(nGrid,nspin)
-
-! Local variables
-
-  integer                       :: iG
-  double precision              :: ra,rb,r,raI,rbI,rI,rs,x,z
-  double precision              :: a_p,x0_p,xx0_p,b_p,c_p,x_p,q_p
-  double precision              :: a_f,x0_f,xx0_f,b_f,c_f,x_f,q_f
-  double precision              :: a_a,x0_a,xx0_a,b_a,c_a,x_a,q_a
-  double precision              :: dfzdz,dxdrs,dxdx_p,dxdx_f,dxdx_a,decdx_p,decdx_f,decdx_a
-  double precision              :: dzdra,dfzdra,drsdra,decdra_p,decdra_f,decdra_a,decdra
-  double precision              :: dzdrb,dfzdrb,drsdrb,decdrb_p,decdrb_f,decdrb_a,decdrb
-  double precision              :: ec_z,ec_p,ec_f,ec_a
-  double precision              :: fz,d2fz
-
-! Output variables
-
-  double precision              :: Ec(nspin)
-
-! Parameters of the functional
-
-  a_p  = +0.0621814D0/2D0
-  x0_p = -0.10498d0
-  b_p  = +3.72744d0
-  c_p  = +12.9352d0
-
-  a_f  = +0.0621814D0/4D0
-  x0_f = -0.325d0
-  b_f  = +7.06042d0
-  c_f  = +18.0578d0
-
-  a_a  = -1d0/(6d0*pi**2)
-  x0_a = -0.0047584D0
-  b_a  = +1.13107d0
-  c_a  = +13.0045d0
-
-! Initialization
-
-  Ec(:) = 0d0
-
-  do iG=1,nGrid
-
-    ra = max(0d0,rhow(iG,1))
-    rb = max(0d0,rhow(iG,2))
-
-    raI = max(0d0,rho(iG,1))
-    rbI = max(0d0,rho(iG,2))
-   
-!   spin-up contribution
-   
-    if(ra > threshold .and. raI > threshold) then
-   
-      r = ra + rb
-      rI = raI + rbI
-
-      rs = (4d0*pi*r/3d0)**(-1d0/3d0)
-      z = (ra - rb)/r
-      x = sqrt(rs)
-   
-      fz = (1d0 + z)**(4d0/3d0) + (1d0 - z)**(4d0/3d0) - 2d0
-      fz = fz/(2d0*(2d0**(1d0/3d0) - 1d0))
-   
-      d2fz = 4d0/(9d0*(2**(1d0/3d0) - 1d0))
-   
-      x_p = x*x + b_p*x + c_p
-      x_f = x*x + b_f*x + c_f
-      x_a = x*x + b_a*x + c_a
-   
-      xx0_p = x0_p*x0_p + b_p*x0_p + c_p
-      xx0_f = x0_f*x0_f + b_f*x0_f + c_f
-      xx0_a = x0_a*x0_a + b_a*x0_a + c_a
-   
-      q_p = sqrt(4d0*c_p - b_p*b_p)
-      q_f = sqrt(4d0*c_f - b_f*b_f)
-      q_a = sqrt(4d0*c_a - b_a*b_a)
-   
-      ec_p = a_p*( log(x**2/x_p) + 2d0*b_p/q_p*atan(q_p/(2d0*x + b_p)) & 
-                 - b_p*x0_p/xx0_p*( log((x - x0_p)**2/x_p) + 2d0*(b_p + 2d0*x0_p)/q_p*atan(q_p/(2d0*x + b_p)) ) )
-   
-      ec_f = a_f*( log(x**2/x_f) + 2d0*b_f/q_f*atan(q_f/(2d0*x + b_f)) & 
-                 - b_f*x0_f/xx0_f*( log((x - x0_f)**2/x_f) + 2d0*(b_f + 2d0*x0_f)/q_f*atan(q_f/(2d0*x + b_f)) ) )
-   
-      ec_a = a_a*( log(x**2/x_a) + 2d0*b_a/q_a*atan(q_a/(2d0*x + b_a)) & 
-                 - b_a*x0_a/xx0_a*( log((x - x0_a)**2/x_a) + 2d0*(b_a + 2d0*x0_a)/q_a*atan(q_a/(2d0*x + b_a)) ) )
-   
-      ec_z = ec_p + ec_a*fz/d2fz*(1d0-z**4) + (ec_f - ec_p)*fz*z**4
-
-      dzdra = (1d0 - z)/r
-      dfzdz = (4d0/3d0)*((1d0 + z)**(1d0/3d0) - (1d0 - z)**(1d0/3d0))/(2d0*(2d0**(1d0/3d0) - 1d0))
-      dfzdra = dzdra*dfzdz
-
-      drsdra = - (36d0*pi)**(-1d0/3d0)*r**(-4d0/3d0)
-      dxdrs  = 0.5d0/sqrt(rs)
-
-      dxdx_p = 2d0*x + b_p
-      dxdx_f = 2d0*x + b_f
-      dxdx_a = 2d0*x + b_a
-
-      decdx_p = a_p*( 2d0/x - 4d0*b_p/( (b_p+2d0*x)**2 + q_p**2) - dxdx_p/x_p &
-                      - b_p*x0_p/xx0_p*( 2/(x-x0_p) - 4d0*(b_p+2d0*x0_p)/( (b_p+2d0*x)**2 + q_p**2) - dxdx_p/x_p ) )
-
-      decdx_f = a_f*( 2d0/x - 4d0*b_f/( (b_f+2d0*x)**2 + q_f**2) - dxdx_f/x_f &
-                      - b_f*x0_f/xx0_f*( 2/(x-x0_f) - 4d0*(b_f+2d0*x0_f)/( (b_f+2d0*x)**2 + q_f**2) - dxdx_f/x_f ) )
-
-      decdx_a = a_a*( 2d0/x - 4d0*b_a/( (b_a+2d0*x)**2 + q_a**2) - dxdx_a/x_a &
-                      - b_a*x0_a/xx0_a*( 2/(x-x0_a) - 4d0*(b_a+2d0*x0_a)/( (b_a+2d0*x)**2 + q_a**2) - dxdx_a/x_a ) )
-
-      decdra_p = drsdra*dxdrs*decdx_p
-      decdra_f = drsdra*dxdrs*decdx_f
-      decdra_a = drsdra*dxdrs*decdx_a
-
-      decdra = decdra_p + decdra_a*fz/d2fz*(1d0-z**4) + ec_a*dfzdra/d2fz*(1d0-z**4) - 4d0*ec_a*fz/d2fz*dzdra*z**3 &
-             + (decdra_f - decdra_p)*fz*z**4 + (ec_f - ec_p)*dfzdra*z**4 + 4d0*(ec_f - ec_p)*fz*dzdra*z**3
-
-      Ec(2) = Ec(2) + weight(iG)*(ec_z + decdra*r)*rI
-   
-    end if
-
-!   spin-down contribution
-   
-    if(rb > threshold .and. rbI > threshold) then
-   
-      r = ra + rb
-      rI = raI + rbI
-
-      rs = (4d0*pi*r/3d0)**(-1d0/3d0)
-      z = (ra - rb)/r
-      x = sqrt(rs)
-   
-      fz = (1d0 + z)**(4d0/3d0) + (1d0 - z)**(4d0/3d0) - 2d0
-      fz = fz/(2d0*(2d0**(1d0/3d0) - 1d0))
-   
-      d2fz = 4d0/(9d0*(2**(1d0/3d0) - 1d0))
-   
-      x_p = x*x + b_p*x + c_p
-      x_f = x*x + b_f*x + c_f
-      x_a = x*x + b_a*x + c_a
-
-      xx0_p = x0_p*x0_p + b_p*x0_p + c_p
-      xx0_f = x0_f*x0_f + b_f*x0_f + c_f
-      xx0_a = x0_a*x0_a + b_a*x0_a + c_a
-   
-      q_p = sqrt(4d0*c_p - b_p*b_p)
-      q_f = sqrt(4d0*c_f - b_f*b_f)
-      q_a = sqrt(4d0*c_a - b_a*b_a)
-   
-      ec_p = a_p*( log(x**2/x_p) + 2d0*b_p/q_p*atan(q_p/(2d0*x + b_p)) & 
-                 - b_p*x0_p/xx0_p*( log((x - x0_p)**2/x_p) + 2d0*(b_p + 2d0*x0_p)/q_p*atan(q_p/(2d0*x + b_p)) ) )
-   
-      ec_f = a_f*( log(x**2/x_f) + 2d0*b_f/q_f*atan(q_f/(2d0*x + b_f)) & 
-                 - b_f*x0_f/xx0_f*( log((x - x0_f)**2/x_f) + 2d0*(b_f + 2d0*x0_f)/q_f*atan(q_f/(2d0*x + b_f)) ) )
-   
-      ec_a = a_a*( log(x**2/x_a) + 2d0*b_a/q_a*atan(q_a/(2d0*x + b_a)) & 
-                 - b_a*x0_a/xx0_a*( log((x - x0_a)**2/x_a) + 2d0*(b_a + 2d0*x0_a)/q_a*atan(q_a/(2d0*x + b_a)) ) )
-
-      ec_z = ec_p + ec_a*fz/d2fz*(1d0-z**4) + (ec_f - ec_p)*fz*z**4
-   
-      dzdrb = -(1d0 + z)/r
-      dfzdz = (4d0/3d0)*((1d0 + z)**(1d0/3d0) - (1d0 - z)**(1d0/3d0))/(2d0*(2d0**(1d0/3d0) - 1d0))
-      dfzdrb = dzdrb*dfzdz
-
-      drsdrb = - (36d0*pi)**(-1d0/3d0)*r**(-4d0/3d0)
-      dxdrs  = 0.5d0/sqrt(rs)
-
-      dxdx_p = 2d0*x + b_p
-      dxdx_f = 2d0*x + b_f
-      dxdx_a = 2d0*x + b_a
-
-      decdx_p = a_p*( 2d0/x - 4d0*b_p/( (b_p+2d0*x)**2 + q_p**2) - dxdx_p/x_p &
-                      - b_p*x0_p/xx0_p*( 2/(x-x0_p) - 4d0*(b_p+2d0*x0_p)/( (b_p+2d0*x)**2 + q_p**2) - dxdx_p/x_p ) )
-
-      decdx_f = a_f*( 2d0/x - 4d0*b_f/( (b_f+2d0*x)**2 + q_f**2) - dxdx_f/x_f &
-                      - b_f*x0_f/xx0_f*( 2/(x-x0_f) - 4d0*(b_f+2d0*x0_f)/( (b_f+2d0*x)**2 + q_f**2) - dxdx_f/x_f ) )
-
-      decdx_a = a_a*( 2d0/x - 4d0*b_a/( (b_a+2d0*x)**2 + q_a**2) - dxdx_a/x_a &
-                      - b_a*x0_a/xx0_a*( 2/(x-x0_a) - 4d0*(b_a+2d0*x0_a)/( (b_a+2d0*x)**2 + q_a**2) - dxdx_a/x_a ) )
-
-      decdrb_p = drsdrb*dxdrs*decdx_p
-      decdrb_f = drsdrb*dxdrs*decdx_f
-      decdrb_a = drsdrb*dxdrs*decdx_a
-
-      decdrb = decdrb_p + decdrb_a*fz/d2fz*(1d0-z**4) + ec_a*dfzdrb/d2fz*(1d0-z**4) - 4d0*ec_a*fz/d2fz*dzdrb*z**3 &
-             + (decdrb_f - decdrb_p)*fz*z**4 + (ec_f - ec_p)*dfzdrb*z**4 + 4d0*(ec_f - ec_p)*fz*dzdrb*z**3
-
-      Ec(2) = Ec(2) + weight(iG)*(ec_z + decdrb*r)*rI
-   
-    end if
-
-  end do
-
-end subroutine UVWN5_lda_correlation_individual_energy

src/eDFT/eDFT_UKS.f90

@@ -311,7 +311,7 @@ subroutine eDFT_UKS(x_rung,x_DFA,c_rung,c_DFA,nEns,wEns,aCC_w1,aCC_w2,nGrid,weig
 
     EJ(1) = 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,1),J(:,:,1)))
     EJ(2) = 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,1),J(:,:,2))) &
-            + 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,1))) !!!!!!
+          + 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,1))) 
     EJ(3) = 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,2)))
 
 !   Exchange energy

src/eDFT/elda_correlation_individual_energy.f90

@@ -39,7 +39,7 @@ subroutine elda_correlation_individual_energy(aLF,nGrid,weight,rhow,rho,Ec)
     r  = ra  + rb
     rI = raI + rbI
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       ec_p  = aLF(1)/(1d0 + aLF(2)*r**(-1d0/6d0) + aLF(3)*r**(-1d0/3d0))
 

src/eDFT/lda_exchange_energy.f90

@@ -27,7 +27,7 @@ subroutine lda_exchange_energy(DFA,LDA_centered,nEns,wEns,aCC_w1,aCC_w2,nGrid,we
 
     case ('US51')
 
-      call US51_lda_exchange_energy(nGrid,weight,rho,Ex,wEns,nEns)
+      call US51_lda_exchange_energy(nGrid,weight,rho,Ex)
 
     case ('RS51')
 

src/eDFT/print_unrestricted_individual_energy.f90

@@ -140,14 +140,14 @@ subroutine print_unrestricted_individual_energy(nEns,ENuc,Ew,ET,EV,EJ,Ex,Ec,Exc,
   write(*,'(A60)') ' IP and EA FROM AUXILIARY ENERGIES '
   write(*,'(A60)') '-------------------------------------------------'
 
-    write(*,'(A40,F16.10,A3)') ' Ionization Potential  1 -> 2 :',Omaux(2)+OmxcDD(2),' au'
+    write(*,'(A43,F16.10,A4)') ' Ionization Potential  1 -> 2:',Omaux(2)+OmxcDD(2),' au'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') ' auxiliary energy contribution  : ',Omaux(2), ' au'
     write(*,'(A44,      F16.10,A3)') '        x  ensemble derivative  : ',OmxDD(2), ' au'
     write(*,'(A44,      F16.10,A3)') '        c  ensemble derivative  : ',OmcDD(2), ' au'
     write(*,'(A44,      F16.10,A3)') '       xc  ensemble derivative  : ',OmxcDD(2),' au'
     write(*,*)
-    write(*,'(A40,F16.10,A3)') ' Electronic Affinity  1 -> 3 :',Omaux(3)+OmxcDD(3),' au'
+    write(*,'(A43,F16.10,A4)') ' Electronic Affinity  1 -> 3:',Omaux(3)+OmxcDD(3),' au'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') ' auxiliary energy contribution  : ',Omaux(3), ' au'
     write(*,'(A44,      F16.10,A3)') '        x  ensemble derivative  : ',OmxDD(3), ' au'
@@ -184,7 +184,7 @@ subroutine print_unrestricted_individual_energy(nEns,ENuc,Ew,ET,EV,EJ,Ex,Ec,Exc,
   end do
   write(*,'(A60)') '-------------------------------------------------'
 
-    write(*,'(A40,F16.10,A3)') ' Ionization Potential  1 -> 2 :',Om(2),    ' au'
+    write(*,'(A43,F16.10,A4)') ' Ionization Potential  1 -> 2:',Om(2),    ' au'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') '     x  energy contribution     : ',Omx(2),   ' au'
     write(*,'(A44,      F16.10,A3)') '     c  energy contribution     : ',Omc(2),   ' au'
@@ -194,7 +194,7 @@ subroutine print_unrestricted_individual_energy(nEns,ENuc,Ew,ET,EV,EJ,Ex,Ec,Exc,
     write(*,'(A44,      F16.10,A3)') '     c  ensemble derivative     : ',OmcDD(2), ' au'
     write(*,'(A44,      F16.10,A3)') '    xc  ensemble derivative     : ',OmxcDD(2),' au'
     write(*,*)
-    write(*,'(A40,F16.10,A3)') ' Electronic Affinity  1 -> 3 :',Om(3),    ' au'
+    write(*,'(A43,F16.10,A4)') ' Electronic Affinity  1 -> 3:',Om(3),    ' au'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') '     x  energy contribution     : ',Omx(3),   ' au'
     write(*,'(A44,      F16.10,A3)') '     c  energy contribution     : ',Omc(3),   ' au'
@@ -207,7 +207,7 @@ subroutine print_unrestricted_individual_energy(nEns,ENuc,Ew,ET,EV,EJ,Ex,Ec,Exc,
 
     write(*,'(A60)') '-------------------------------------------------'
 
-    write(*,'(A40,F16.10,A3)') ' Ionization Potential 1 -> 2 :',Om(2)*HaToeV,    ' eV'
+    write(*,'(A43,F16.10,A4)') ' Ionization Potential 1 -> 2:',Om(2)*HaToeV,    ' eV'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') '     x  energy contribution     : ',Omx(2)*HaToeV,   ' eV'
     write(*,'(A44,      F16.10,A3)') '     c  energy contribution     : ',Omc(2)*HaToeV,   ' eV'
@@ -217,7 +217,7 @@ subroutine print_unrestricted_individual_energy(nEns,ENuc,Ew,ET,EV,EJ,Ex,Ec,Exc,
     write(*,'(A44,      F16.10,A3)') '     c  ensemble derivative     : ',OmcDD(2)*HaToeV, ' eV'
     write(*,'(A44,      F16.10,A3)') '    xc  ensemble derivative     : ',OmxcDD(2)*HaToeV,' eV'
     write(*,*)
-    write(*,'(A40,F16.10,A3)') ' Electronic Affinity 1 -> 3 :',Om(3)*HaToeV,    ' eV'
+    write(*,'(A43,F16.10,A4)') ' Electronic Affinity 1 -> 3:',Om(3)*HaToeV,    ' eV'
     write(*,*)
     write(*,'(A44,      F16.10,A3)') '     x  energy contribution     : ',Omx(3)*HaToeV,   ' eV'
     write(*,'(A44,      F16.10,A3)') '     c  energy contribution     : ',Omc(3)*HaToeV,   ' eV'

src/eDFT/restricted_elda_correlation_individual_energy.f90

@@ -33,7 +33,7 @@ subroutine restricted_elda_correlation_individual_energy(aMFL,nGrid,weight,rhow,
     r  = max(0d0,rhow(iG))
     rI = max(0d0,rho(iG))
 
-    if(r > threshold .and. rI > threshold) then
+    if(r > threshold .or. rI > threshold) then
 
       ec_p  = aMFL(1)/(1d0 + aMFL(2)*r**(-1d0/6d0) + aMFL(3)*r**(-1d0/3d0))
 

src/eDFT/unrestricted_correlation_energy.f90

@@ -38,13 +38,13 @@ subroutine unrestricted_correlation_energy(rung,DFA,nEns,wEns,nGrid,weight,rho,d
 
     case(1) 
 
-      call unrestricted_lda_correlation_energy(DFA,nEns,wEns(:),nGrid,weight(:),rho(:,:),Ec(:))
+      call unrestricted_lda_correlation_energy(DFA,nEns,wEns,nGrid,weight,rho,Ec)
 
 !   GGA functionals
 
     case(2) 
 
-      call unrestricted_gga_correlation_energy(DFA,nEns,wEns(:),nGrid,weight(:),rho(:,:),drho(:,:,:),Ec(:))
+      call unrestricted_gga_correlation_energy(DFA,nEns,wEns,nGrid,weight,rho,drho,Ec)
 
 !   Hybrid functionals
 
@@ -52,8 +52,8 @@ subroutine unrestricted_correlation_energy(rung,DFA,nEns,wEns,nGrid,weight,rho,d
 
       aC = 0.81d0
 
-      call unrestricted_lda_correlation_energy(DFA,nEns,wEns(:),nGrid,weight(:),rho(:,:),EcLDA(:))
+      call unrestricted_lda_correlation_energy(DFA,nEns,wEns,nGrid,weight,rho,EcLDA)
-      call unrestricted_gga_correlation_energy(DFA,nEns,wEns(:),nGrid,weight(:),rho(:,:),drho(:,:,:),EcGGA(:))
+      call unrestricted_gga_correlation_energy(DFA,nEns,wEns,nGrid,weight,rho,drho,EcGGA)
 
       Ec(:) = EcLDA(:) + aC*(EcGGA(:) - EcLDA(:)) 
 

src/eDFT/unrestricted_individual_energy.f90

@@ -42,7 +42,6 @@ subroutine unrestricted_individual_energy(x_rung,x_DFA,c_rung,c_DFA,LDA_centered
   double precision,intent(in)   :: Fc(nBas,nBas,nspin)
   double precision              :: Ew
 
-
 ! Local variables
 
   double precision              :: ET(nspin,nEns)
@@ -107,24 +106,14 @@ subroutine unrestricted_individual_energy(x_rung,x_DFA,c_rung,c_DFA,LDA_centered
 
     EJ(2,iEns) =       trace_matrix(nBas,matmul(P(:,:,1,iEns),J(:,:,2))) &
                +       trace_matrix(nBas,matmul(P(:,:,2,iEns),J(:,:,1))) &
- ! 2.0d0*trace_matrix(nBas,matmul(P(:,:,1,iEns),J(:,:,2))) &
                - 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,1),J(:,:,2)))     &
                - 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,1)))
 
-   ! if (iEns.ne.2) then
     EJ(3,iEns) =       trace_matrix(nBas,matmul(P(:,:,2,iEns),J(:,:,2))) &
                - 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,2)))
-   ! end if
+
   end do
      
- ! if (nO(2) > 1) then
-   ! EJ(3,2) = trace_matrix(nBas,matmul(P(:,:,2,iEns),J(:,:,2))) &
-    !           - 0.5d0*trace_matrix(nBas,matmul(Pw(:,:,2),J(:,:,2)))
- ! else
- ! EJ(3,2) = trace_matrix(nBas,matmul(P(:,:,2,iEns),J(:,:,2)))
- ! end if
-  
-
 !------------------------------------------------------------------------
 ! Checking Hartree contributions for each individual states
 !------------------------------------------------------------------------
@@ -143,7 +132,7 @@ subroutine unrestricted_individual_energy(x_rung,x_DFA,c_rung,c_DFA,LDA_centered
 !------------------------------------------------------------------------
 ! Individual exchange energy
 !------------------------------------------------------------------------
-  print*,'old Ex(2,2)=',Ex(2,2)
+
   do iEns=1,nEns
     do ispin=1,nspin
       call exchange_individual_energy(x_rung,x_DFA,LDA_centered,nEns,wEns,aCC_w1,aCC_w2,nGrid,weight,nBas,ERI, &
@@ -151,7 +140,6 @@ subroutine unrestricted_individual_energy(x_rung,x_DFA,c_rung,c_DFA,LDA_centered
                                       rho(:,ispin,iEns),drho(:,:,ispin,iEns),Ex(ispin,iEns))
     end do
   end do
-  print*,'new Ex(2,2)=',Ex(2,2)
 
 !------------------------------------------------------------------------
 ! Checking exchange contributions for each individual states