more cleaning in functionals

2024-12-21 11:03:29 +01:00 · 2020-03-30 16:00:50 +02:00 · 2020-03-30 16:00:50 +02:00 · 9d2d00f040
commit 9d2d00f040
parent 192854f771
10 changed files with 317 additions and 438 deletions
--- a/src/dft_utils_one_e/ec_lyp.irp.f
+++ b/src/dft_utils_one_e/ec_lyp.irp.f
@ -1,125 +0,0 @@
-subroutine give_all_stuffs_in_r_for_lyp_88(r,rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2)
- implicit none
- double precision, intent(in) :: r(3)
- double precision, intent(out) :: rho_a(N_states),rho_b(N_states),grad_rho_a_2(N_states),grad_rho_b_2(N_states),grad_rho_2(N_states),rho(N_states)
- double precision :: grad_rho_a(3,N_states),grad_rho_b(3,N_states),grad_rho_a_b(N_states)
- double precision :: grad_aos_array(3,ao_num),aos_array(ao_num)
-
- call density_and_grad_alpha_beta_and_all_aos_and_grad_aos_at_r(r,rho_a,rho_b, grad_rho_a, grad_rho_b, aos_array, grad_aos_array)
- integer :: i,istate
- rho = rho_a + rho_b
- grad_rho_a_2 = 0.d0
- grad_rho_b_2 = 0.d0
- grad_rho_a_b = 0.d0
- do istate = 1, N_states
-  do i = 1, 3 
-   grad_rho_a_2(istate) += grad_rho_a(i,istate) * grad_rho_a(i,istate)
-   grad_rho_b_2(istate) += grad_rho_b(i,istate) * grad_rho_b(i,istate)
-   grad_rho_a_b(istate) += grad_rho_a(i,istate) * grad_rho_b(i,istate)
-  enddo
- enddo
- grad_rho_2 = grad_rho_a_2 + grad_rho_b_2 + 2.d0 * grad_rho_a_b
-
-end
-
-
-double precision function ec_lyp_88(rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2)
-
- implicit none
-
- BEGIN_DOC
-! LYP functional of the Lee, Yan, Parr, Phys. Rev B 1988, Vol 37, page 785.  
-! The expression used is the one by Miehlich, Savin, Stoll, Preuss, CPL, 1989 which gets rid of the laplacian of the density
- END_DOC
-
- include 'constants.include.F'
-
-! Input variables
- double precision, intent(in) :: rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2
-! Local variables
- double precision :: a,b,c,d,c_f,omega,delta
- double precision :: rho_13,rho_inv_13,rho_83,rho_113,rho_inv_113,denom
- double precision :: thr,huge_num,rho_inv
- double precision :: cst_2_113,cst_8_3,rho_2,rho_a_2,rho_b_2
- double precision :: tmp1,tmp2,tmp3,tmp4
- double precision :: big1,big2,big3
-
-
-! Constants of the LYP correlation functional
-
- a = 0.04918d0
- b = 0.132d0
- c = 0.2533d0
- d = 0.349d0
-
- ec_lyp_88 = 0.d0
-
- thr = 1d-15
- huge_num = 1.d0/thr
- if(dabs(rho_a).lt.thr)then
-  return 
- endif
-
- if(dabs(rho_b).lt.thr)then
-  return 
- endif
-
- if(rho.lt.0.d0)then
-  print*,'pb !! rho.lt.0.d0'
-  stop
- endif
-
- rho_13  = rho**(1.d0/3.d0)
- rho_113 = rho**(11.d0/3.d0)
-
- if(dabs(rho_13) < thr) then
-  rho_inv_13 = huge_num
- else
-  rho_inv_13 = 1.d0/rho_13
- endif
-
- if (dabs(rho_113) < thr) then
-  rho_inv_113 = huge_num
- else
-  rho_inv_113 = 1.d0/rho_113
- endif
-
- if (dabs(rho) < thr) then
-  rho_inv = huge_num
- else
-  rho_inv = 1.d0/rho
- endif
-
-! Useful quantities to predefine
-
- denom = 1d0/(1d0 + d*rho_inv_13)
- omega = rho_inv_113*exp(-c*rho_inv_13)*denom
- delta = c*rho_inv_13 + d*rho_inv_13*denom
- c_f   = 0.3d0*(3.d0*pi*pi)**(2.d0/3.d0)
-
- rho_2   = rho  *rho
- rho_a_2 = rho_a*rho_a
- rho_b_2 = rho_b*rho_b
-
- cst_2_113 = 2.d0**(11.d0/3.d0)
- cst_8_3   = 8.d0/3.d0
-
- ! first term in the equation (2) of Preuss CPL, 1989
-
- big1 = 4.d0*denom*rho_a*rho_b*rho_inv
-
- tmp1 = cst_2_113*c_f*(rho_a**cst_8_3 + rho_b**cst_8_3)
- tmp2 = (47.d0/18.d0 - 7.d0/18.d0*delta)*grad_rho_2
- tmp3 = - (5d0/2d0 - 1.d0/18d0*delta)*(grad_rho_a_2 + grad_rho_b_2)
- tmp4 = - (delta - 11d0)/9d0*(rho_a*rho_inv*grad_rho_a_2 + rho_b*rho_inv*grad_rho_b_2)
- big2 = rho_a*rho_b*(tmp1 + tmp2 + tmp3 + tmp4)
-
- tmp1 = -2d0/3d0*rho_2*grad_rho_2
- tmp2 = grad_rho_b_2*(2d0/3d0*rho_2 - rho_a_2)
- tmp3 = grad_rho_a_2*(2d0/3d0*rho_2 - rho_b_2)
- big3 = tmp1 + tmp2 + tmp3
-
- ec_lyp_88 = -a*big1 -a*b*omega*big2 -a*b*omega*big3
-
-end
-
--- a/src/dft_utils_one_e/ec_lyp_2.irp.f
+++ b/src/dft_utils_one_e/ec_lyp_2.irp.f
@ -1,28 +0,0 @@
-double precision function ec_lyp2(RhoA,RhoB,GA,GB,GAB)
- include 'constants.include.F'
- implicit none
- double precision, intent(in) :: RhoA,RhoB,GA,GB,GAB
- double precision :: Tol,caa,cab,cac,cad,cae,RA,RB,comega,cdelta,cLaa,cLbb,cLab,E
- ec_lyp2 = 0.d0
- Tol=1D-14
- E=2.718281828459045D0
- caa=0.04918D0
- cab=0.132D0
- cac=0.2533D0
- cad=0.349D0
- cae=(2D0**(11D0/3D0))*((3D0/10D0)*((3D0*(Pi**2D0))**(2D0/3D0)))
-
-
-  RA = MAX(RhoA,0D0)
-  RB = MAX(RhoB,0D0)
-  IF ((RA.gt.Tol).OR.(RB.gt.Tol)) THEN
-   IF ((RA.gt.Tol).AND.(RB.gt.Tol)) THEN
-    comega = 1D0/(E**(cac/(RA+RB)**(1D0/3D0))*(RA+RB)**(10D0/3D0)*(cad+(RA+RB)**(1D0/3D0)))
-    cdelta = (cac+cad+(cac*cad)/(RA+RB)**(1D0/3D0))/(cad+(RA+RB)**(1D0/3D0))
-    cLaa = (cab*comega*RB*(RA-3D0*cdelta*RA-9D0*RB-((-11D0+cdelta)*RA**2D0)/(RA+RB)))/9D0
-    cLbb = (cab*comega*RA*(-9D0*RA+(RB*(RA-3D0*cdelta*RA-4D0*(-3D0+cdelta)*RB))/(RA+RB)))/9D0
-    cLab = cab*comega*(((47D0-7D0*cdelta)*RA*RB)/9D0-(4D0*(RA+RB)**2D0)/3D0)
-    ec_lyp2 = -(caa*(cLaa*GA+cLab*GAB+cLbb*GB+cab*cae*comega*RA*RB*(RA**(8D0/3D0)+RB**(8D0/3D0))+(4D0*RA*RB)/(RA+RB+cad*(RA+RB)**(2D0/3D0))))
-  endif
- endif
-end
--- a/src/dft_utils_one_e/ec_scan.irp.f
+++ b/src/dft_utils_one_e/ec_scan.irp.f
@ -1,99 +0,0 @@
-double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
- include 'constants.include.F'
- implicit none
- double precision, intent(in) :: rho_a,rho_b,tau,grad_rho_2
- double precision :: cst_13,cst_23,cst_43,cst_53,rho_inv,cst_18,cst_3pi2
- double precision :: thr,nup,ndo,xi,s,spin_d,drho,drho2,rho,inv_1alph,e_c_lsda1,h0
- double precision :: rs,t_w,t_unif,ds_xi,alpha,fc_alpha,step_f,cst_1alph,beta_inf
- double precision :: c_1c,c_2c,d_c,e_c_ldsa1,h1,phi,t,beta_rs,gama,a,w_1,g_at2,phi_3,e_c_1
- double precision :: b_1c,b_2c,b_3c,dx_xi,gc_xi,e_c_lsda0,w_0,g_inf,cx_xi,x_inf,f0,e_c_0
- thr = 1.d-12
- nup = max(rho_a,thr)
- ndo = max(rho_b,thr)
- rho = nup + ndo 
- ec_scan = 0.d0
- if((rho).lt.thr)return
- ! constants ...
- rho_inv  = 1.d0/rho
- cst_13   = 1.d0/3.d0
- cst_23   = 2.d0 * cst_13
- cst_43   = 4.d0 * cst_13
- cst_53   = 5.d0 * cst_13
- cst_18   = 1.d0/8.d0
- cst_3pi2 = 3.d0 * pi*pi
- drho2    = max(grad_rho_2,thr)
- drho     = dsqrt(drho2)
- if((nup-ndo).gt.0.d0)then
-  spin_d  = max(nup-ndo,thr) 
- else
-  spin_d  = min(nup-ndo,-thr) 
- endif
- c_1c     = 0.64d0
- c_2c     = 1.5d0
- d_c      = 0.7d0
- b_1c     = 0.0285764d0
- b_2c     = 0.0889d0
- b_3c     = 0.125541d0
- gama     = 0.031091d0
- ! correlation energy lsda1
- call ec_only_lda_sr(0.d0,nup,ndo,e_c_lsda1)
-
- ! correlation energy per particle 
- e_c_lsda1 = e_c_lsda1/rho         
- xi       = spin_d/rho
- rs       = (cst_43 * pi * rho)**(-cst_13)
- s        = drho/( 2.d0 * cst_3pi2**(cst_13) * rho**cst_43  )
- t_w      = drho2 * cst_18 * rho_inv
- ds_xi    = 0.5d0 * ( (1.d0+xi)**cst_53 + (1.d0 - xi)**cst_53)
- t_unif   = 0.3d0 * (cst_3pi2)**cst_23 * rho**cst_53*ds_xi
- t_unif   = max(t_unif,thr)
- alpha    = (tau - t_w)/t_unif
- cst_1alph= 1.d0 - alpha
- if(cst_1alph.gt.0.d0)then
-  cst_1alph= max(cst_1alph,thr)
- else
-  cst_1alph= min(cst_1alph,-thr)
- endif
- inv_1alph= 1.d0/cst_1alph
- phi      = 0.5d0 * ( (1.d0+xi)**cst_23 + (1.d0 - xi)**cst_23)
- phi_3    = phi*phi*phi
- t        = (cst_3pi2/16.d0)**cst_13 * s / (phi * rs**0.5d0)
- w_1      = dexp(-e_c_lsda1/(gama * phi_3)) - 1.d0
- a        = beta_rs(rs) /(gama * w_1)
- g_at2    = 1.d0/(1.d0 + 4.d0 * a*t*t)**0.25d0
- h1       = gama * phi_3 * dlog(1.d0 + w_1 * (1.d0 - g_at2))
- ! interpolation function 
-
- if(cst_1alph.gt.0.d0)then
-  fc_alpha = dexp(-c_1c * alpha * inv_1alph) 
- else
-  fc_alpha = - d_c * dexp(c_2c * inv_1alph) 
- endif
- ! first part of the correlation energy 
- e_c_1    = e_c_lsda1 + h1
- 
- dx_xi    =  0.5d0 * ( (1.d0+xi)**cst_43 + (1.d0 - xi)**cst_43)
- gc_xi    = (1.d0 - 2.3631d0 * (dx_xi - 1.d0) ) * (1.d0 - xi**12.d0)
- e_c_lsda0= - b_1c / (1.d0 + b_2c * rs**0.5d0 + b_3c * rs)
- w_0      = dexp(-e_c_lsda0/b_1c) - 1.d0
- beta_inf = 0.066725d0 * 0.1d0 / 0.1778d0
- cx_xi    = -3.d0/(4.d0*pi) * (9.d0 * pi/4.d0)**cst_13 * dx_xi
-
- x_inf   = 0.128026d0
- f0       = -0.9d0
- g_inf    = 1.d0/(1.d0 + 4.d0 * x_inf * s*s)**0.25d0
- 
- h0       = b_1c * dlog(1.d0 + w_0 * (1.d0 - g_inf)) 
- e_c_0    = (e_c_lsda0 + h0) * gc_xi
-
- ec_scan = e_c_1 + fc_alpha * (e_c_0 - e_c_1)
-end
-
-
-double precision function beta_rs(rs)
- implicit none
- double precision, intent(in) ::rs
- beta_rs = 0.066725d0 * (1.d0 + 0.1d0 * rs)/(1.d0 + 0.1778d0 * rs)
-
-end
-
--- a/src/dft_utils_one_e/ec_scan_2.irp.f
+++ b/src/dft_utils_one_e/ec_scan_2.irp.f
@ -1,100 +0,0 @@
-double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
- include 'constants.include.F'
- implicit none
- double precision, intent(in) :: rho_a,rho_b,tau,grad_rho_2
- double precision :: cst_13,cst_23,cst_43,cst_53,rho_inv,cst_18,cst_3pi2
- double precision :: thr,nup,ndo,xi,s,spin_d,drho,drho2,rho,inv_1alph,e_c_lsda1,h0
- double precision :: rs,t_w,t_unif,ds_xi,alpha,fc_alpha,step_f,cst_1alph,beta_inf
- double precision :: c_1c,c_2c,d_c,e_c_ldsa1,h1,phi,t,beta_rs,gama,a,w_1,g_at2,phi_3,e_c_1
- double precision :: b_1c,b_2c,b_3c,dx_xi,gc_xi,e_c_lsda0,w_0,g_inf,cx_xi,x_inf,f0,e_c_0
- thr = 1.d-12
- nup = max(rho_a,thr)
- ndo = max(rho_b,thr)
- rho = nup + ndo 
- ec_scan = 0.d0
- if((rho).lt.thr)return
- ! constants ...
- rho_inv  = 1.d0/rho
- cst_13   = 1.d0/3.d0
- cst_23   = 2.d0 * cst_13
- cst_43   = 4.d0 * cst_13
- cst_53   = 5.d0 * cst_13
- cst_18   = 1.d0/8.d0
- cst_3pi2 = 3.d0 * pi*pi
- drho2    = max(grad_rho_2,thr)
- drho     = dsqrt(drho2)
- if((nup-ndo).gt.0.d0)then
-  spin_d  = max(nup-ndo,thr) 
- else
-  spin_d  = min(nup-ndo,-thr) 
- endif
- c_1c     = 0.64d0
- c_2c     = 1.5d0
- d_c      = 0.7d0
- b_1c     = 0.0285764d0
- b_2c     = 0.0889d0
- b_3c     = 0.125541d0
- gama     = 0.031091d0
- ! correlation energy lsda1
- call ec_only_lda_sr(0.d0,nup,ndo,e_c_lsda1)
-          
- xi       = spin_d/rho
- rs       = (cst_43 * pi * rho)**(-cst_13)
- s        = drho/( 2.d0 * cst_3pi2**(cst_13) * rho**cst_43  )
- t_w      = drho2 * cst_18 * rho_inv
- ds_xi    = 0.5d0 * ( (1.d0+xi)**cst_53 + (1.d0 - xi)**cst_53)
- t_unif   = 0.3d0 * (cst_3pi2)**cst_23 * rho**cst_53*ds_xi
- t_unif   = max(t_unif,thr)
- alpha    = (tau - t_w)/t_unif
- cst_1alph= 1.d0 - alpha
- if(cst_1alph.gt.0.d0)then
-  cst_1alph= max(cst_1alph,thr)
- else
-  cst_1alph= min(cst_1alph,-thr)
- endif
- inv_1alph= 1.d0/cst_1alph
- phi      = 0.5d0 * ( (1.d0+xi)**cst_23 + (1.d0 - xi)**cst_23)
- phi_3    = phi*phi*phi
- t        = (cst_3pi2/16.d0)**cst_13 * s / (phi * rs**0.5d0)
- w_1      = dexp(-e_c_lsda1/(gama * phi_3)) - 1.d0
- a        = beta_rs(rs) /(gama * w_1)
- g_at2    = 1.d0/(1.d0 + 4.d0 * a*t*t)**0.25d0
- h1       = gama * phi_3 * dlog(1.d0 + w_1 * (1.d0 - g_at2))
- ! interpolation function 
- fc_alpha = dexp(-c_1c * alpha * inv_1alph) * step_f(cst_1alph) - d_c * dexp(c_2c * inv_1alph) * step_f(-cst_1alph) 
- ! first part of the correlation energy 
- e_c_1    = e_c_lsda1 + h1
- 
- dx_xi    =  0.5d0 * ( (1.d0+xi)**cst_43 + (1.d0 - xi)**cst_43)
- gc_xi    = (1.d0 - 2.3631d0 * (dx_xi - 1.d0) ) * (1.d0 - xi**12.d0)
- e_c_lsda0= - b_1c / (1.d0 + b_2c * rs**0.5d0 + b_3c * rs)
- w_0      = dexp(-e_c_lsda0/b_1c) - 1.d0
- beta_inf = 0.066725d0 * 0.1d0 / 0.1778d0
- cx_xi    = -3.d0/(4.d0*pi) * (9.d0 * pi/4.d0)**cst_13 * dx_xi
-
- x_inf   = 0.128026d0
- f0       = -0.9d0
- g_inf    = 1.d0/(1.d0 + 4.d0 * x_inf * s*s)**0.25d0
- 
- h0       = b_1c * dlog(1.d0 + w_0 * (1.d0 - g_inf)) 
- e_c_0    = (e_c_lsda0 + h0) * gc_xi
-
- ec_scan = e_c_1 + fc_alpha * (e_c_0 - e_c_1)
-end
-
-double precision function step_f(x)
- implicit none
- double precision, intent(in) :: x
- if(x.lt.0.d0)then
-  step_f = 0.d0
- else
-  step_f = 1.d0 
- endif
-end             
-
-double precision function beta_rs(rs)
- implicit none
- double precision, intent(in) ::rs
- beta_rs = 0.066725d0 * (1.d0 + 0.1d0 * rs)/(1.d0 + 0.1778d0 * rs)
-
-end
--- a/src/dft_utils_one_e/effective_pot.irp.f
+++ b/src/dft_utils_one_e/effective_pot.irp.f
@ -7,8 +7,11 @@
 ! Effective_one_e_potential(i,j) = $\rangle i_{MO}| v_{H}^{sr} |j_{MO}\rangle  + \rangle i_{MO}| h_{core} |j_{MO}\rangle  + \rangle i_{MO}|v_{xc} |j_{MO}\rangle$
 !
 ! on the |MO| basis
+! 
 ! Taking the expectation value does not provide any energy, but
+!
 ! effective_one_e_potential(i,j) is the potential coupling DFT and WFT part to
+!
 ! be used in any WFT calculation.
 !
 END_DOC
--- a/src/dft_utils_one_e/garbage_func.irp.f
+++ b/src/dft_utils_one_e/garbage_func.irp.f
@ -0,0 +1,264 @@
+
+subroutine give_all_stuffs_in_r_for_lyp_88(r,rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2)
+ implicit none
+ double precision, intent(in) :: r(3)
+ double precision, intent(out) :: rho_a(N_states),rho_b(N_states),grad_rho_a_2(N_states),grad_rho_b_2(N_states),grad_rho_2(N_states),rho(N_states)
+ double precision :: grad_rho_a(3,N_states),grad_rho_b(3,N_states),grad_rho_a_b(N_states)
+ double precision :: grad_aos_array(3,ao_num),aos_array(ao_num)
+
+ call density_and_grad_alpha_beta_and_all_aos_and_grad_aos_at_r(r,rho_a,rho_b, grad_rho_a, grad_rho_b, aos_array, grad_aos_array)
+ integer :: i,istate
+ rho = rho_a + rho_b
+ grad_rho_a_2 = 0.d0
+ grad_rho_b_2 = 0.d0
+ grad_rho_a_b = 0.d0
+ do istate = 1, N_states
+  do i = 1, 3 
+   grad_rho_a_2(istate) += grad_rho_a(i,istate) * grad_rho_a(i,istate)
+   grad_rho_b_2(istate) += grad_rho_b(i,istate) * grad_rho_b(i,istate)
+   grad_rho_a_b(istate) += grad_rho_a(i,istate) * grad_rho_b(i,istate)
+  enddo
+ enddo
+ grad_rho_2 = grad_rho_a_2 + grad_rho_b_2 + 2.d0 * grad_rho_a_b
+
+end
+
+
+double precision function ec_lyp_88(rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2)
+
+ implicit none
+
+ BEGIN_DOC
+! LYP functional of the Lee, Yan, Parr, Phys. Rev B 1988, Vol 37, page 785.  
+! The expression used is the one by Miehlich, Savin, Stoll, Preuss, CPL, 1989 which gets rid of the laplacian of the density
+ END_DOC
+
+ include 'constants.include.F'
+
+! Input variables
+ double precision, intent(in) :: rho,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_2
+! Local variables
+ double precision :: a,b,c,d,c_f,omega,delta
+ double precision :: rho_13,rho_inv_13,rho_83,rho_113,rho_inv_113,denom
+ double precision :: thr,huge_num,rho_inv
+ double precision :: cst_2_113,cst_8_3,rho_2,rho_a_2,rho_b_2
+ double precision :: tmp1,tmp2,tmp3,tmp4
+ double precision :: big1,big2,big3
+
+
+! Constants of the LYP correlation functional
+
+ a = 0.04918d0
+ b = 0.132d0
+ c = 0.2533d0
+ d = 0.349d0
+
+ ec_lyp_88 = 0.d0
+
+ thr = 1d-15
+ huge_num = 1.d0/thr
+ if(dabs(rho_a).lt.thr)then
+  return 
+ endif
+
+ if(dabs(rho_b).lt.thr)then
+  return 
+ endif
+
+ if(rho.lt.0.d0)then
+  print*,'pb !! rho.lt.0.d0'
+  stop
+ endif
+
+ rho_13  = rho**(1.d0/3.d0)
+ rho_113 = rho**(11.d0/3.d0)
+
+ if(dabs(rho_13) < thr) then
+  rho_inv_13 = huge_num
+ else
+  rho_inv_13 = 1.d0/rho_13
+ endif
+
+ if (dabs(rho_113) < thr) then
+  rho_inv_113 = huge_num
+ else
+  rho_inv_113 = 1.d0/rho_113
+ endif
+
+ if (dabs(rho) < thr) then
+  rho_inv = huge_num
+ else
+  rho_inv = 1.d0/rho
+ endif
+
+! Useful quantities to predefine
+
+ denom = 1d0/(1d0 + d*rho_inv_13)
+ omega = rho_inv_113*exp(-c*rho_inv_13)*denom
+ delta = c*rho_inv_13 + d*rho_inv_13*denom
+ c_f   = 0.3d0*(3.d0*pi*pi)**(2.d0/3.d0)
+
+ rho_2   = rho  *rho
+ rho_a_2 = rho_a*rho_a
+ rho_b_2 = rho_b*rho_b
+
+ cst_2_113 = 2.d0**(11.d0/3.d0)
+ cst_8_3   = 8.d0/3.d0
+
+ ! first term in the equation (2) of Preuss CPL, 1989
+
+ big1 = 4.d0*denom*rho_a*rho_b*rho_inv
+
+ tmp1 = cst_2_113*c_f*(rho_a**cst_8_3 + rho_b**cst_8_3)
+ tmp2 = (47.d0/18.d0 - 7.d0/18.d0*delta)*grad_rho_2
+ tmp3 = - (5d0/2d0 - 1.d0/18d0*delta)*(grad_rho_a_2 + grad_rho_b_2)
+ tmp4 = - (delta - 11d0)/9d0*(rho_a*rho_inv*grad_rho_a_2 + rho_b*rho_inv*grad_rho_b_2)
+ big2 = rho_a*rho_b*(tmp1 + tmp2 + tmp3 + tmp4)
+
+ tmp1 = -2d0/3d0*rho_2*grad_rho_2
+ tmp2 = grad_rho_b_2*(2d0/3d0*rho_2 - rho_a_2)
+ tmp3 = grad_rho_a_2*(2d0/3d0*rho_2 - rho_b_2)
+ big3 = tmp1 + tmp2 + tmp3
+
+ ec_lyp_88 = -a*big1 -a*b*omega*big2 -a*b*omega*big3
+
+end
+
+double precision function ec_lyp2(RhoA,RhoB,GA,GB,GAB)
+ include 'constants.include.F'
+ implicit none
+ double precision, intent(in) :: RhoA,RhoB,GA,GB,GAB
+ double precision :: Tol,caa,cab,cac,cad,cae,RA,RB,comega,cdelta,cLaa,cLbb,cLab,E
+ ec_lyp2 = 0.d0
+ Tol=1D-14
+ E=2.718281828459045D0
+ caa=0.04918D0
+ cab=0.132D0
+ cac=0.2533D0
+ cad=0.349D0
+ cae=(2D0**(11D0/3D0))*((3D0/10D0)*((3D0*(Pi**2D0))**(2D0/3D0)))
+
+
+  RA = MAX(RhoA,0D0)
+  RB = MAX(RhoB,0D0)
+  IF ((RA.gt.Tol).OR.(RB.gt.Tol)) THEN
+   IF ((RA.gt.Tol).AND.(RB.gt.Tol)) THEN
+    comega = 1D0/(E**(cac/(RA+RB)**(1D0/3D0))*(RA+RB)**(10D0/3D0)*(cad+(RA+RB)**(1D0/3D0)))
+    cdelta = (cac+cad+(cac*cad)/(RA+RB)**(1D0/3D0))/(cad+(RA+RB)**(1D0/3D0))
+    cLaa = (cab*comega*RB*(RA-3D0*cdelta*RA-9D0*RB-((-11D0+cdelta)*RA**2D0)/(RA+RB)))/9D0
+    cLbb = (cab*comega*RA*(-9D0*RA+(RB*(RA-3D0*cdelta*RA-4D0*(-3D0+cdelta)*RB))/(RA+RB)))/9D0
+    cLab = cab*comega*(((47D0-7D0*cdelta)*RA*RB)/9D0-(4D0*(RA+RB)**2D0)/3D0)
+    ec_lyp2 = -(caa*(cLaa*GA+cLab*GAB+cLbb*GB+cab*cae*comega*RA*RB*(RA**(8D0/3D0)+RB**(8D0/3D0))+(4D0*RA*RB)/(RA+RB+cad*(RA+RB)**(2D0/3D0))))
+  endif
+ endif
+end
+
+double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
+ include 'constants.include.F'
+ implicit none
+ double precision, intent(in) :: rho_a,rho_b,tau,grad_rho_2
+ double precision :: cst_13,cst_23,cst_43,cst_53,rho_inv,cst_18,cst_3pi2
+ double precision :: thr,nup,ndo,xi,s,spin_d,drho,drho2,rho,inv_1alph,e_c_lsda1,h0
+ double precision :: rs,t_w,t_unif,ds_xi,alpha,fc_alpha,step_f,cst_1alph,beta_inf
+ double precision :: c_1c,c_2c,d_c,e_c_ldsa1,h1,phi,t,beta_rs,gama,a,w_1,g_at2,phi_3,e_c_1
+ double precision :: b_1c,b_2c,b_3c,dx_xi,gc_xi,e_c_lsda0,w_0,g_inf,cx_xi,x_inf,f0,e_c_0
+ thr = 1.d-12
+ nup = max(rho_a,thr)
+ ndo = max(rho_b,thr)
+ rho = nup + ndo 
+ ec_scan = 0.d0
+ if((rho).lt.thr)return
+ ! constants ...
+ rho_inv  = 1.d0/rho
+ cst_13   = 1.d0/3.d0
+ cst_23   = 2.d0 * cst_13
+ cst_43   = 4.d0 * cst_13
+ cst_53   = 5.d0 * cst_13
+ cst_18   = 1.d0/8.d0
+ cst_3pi2 = 3.d0 * pi*pi
+ drho2    = max(grad_rho_2,thr)
+ drho     = dsqrt(drho2)
+ if((nup-ndo).gt.0.d0)then
+  spin_d  = max(nup-ndo,thr) 
+ else
+  spin_d  = min(nup-ndo,-thr) 
+ endif
+ c_1c     = 0.64d0
+ c_2c     = 1.5d0
+ d_c      = 0.7d0
+ b_1c     = 0.0285764d0
+ b_2c     = 0.0889d0
+ b_3c     = 0.125541d0
+ gama     = 0.031091d0
+ ! correlation energy lsda1
+ call ec_only_lda_sr(0.d0,nup,ndo,e_c_lsda1)
+
+ ! correlation energy per particle 
+ e_c_lsda1 = e_c_lsda1/rho         
+ xi       = spin_d/rho
+ rs       = (cst_43 * pi * rho)**(-cst_13)
+ s        = drho/( 2.d0 * cst_3pi2**(cst_13) * rho**cst_43  )
+ t_w      = drho2 * cst_18 * rho_inv
+ ds_xi    = 0.5d0 * ( (1.d0+xi)**cst_53 + (1.d0 - xi)**cst_53)
+ t_unif   = 0.3d0 * (cst_3pi2)**cst_23 * rho**cst_53*ds_xi
+ t_unif   = max(t_unif,thr)
+ alpha    = (tau - t_w)/t_unif
+ cst_1alph= 1.d0 - alpha
+ if(cst_1alph.gt.0.d0)then
+  cst_1alph= max(cst_1alph,thr)
+ else
+  cst_1alph= min(cst_1alph,-thr)
+ endif
+ inv_1alph= 1.d0/cst_1alph
+ phi      = 0.5d0 * ( (1.d0+xi)**cst_23 + (1.d0 - xi)**cst_23)
+ phi_3    = phi*phi*phi
+ t        = (cst_3pi2/16.d0)**cst_13 * s / (phi * rs**0.5d0)
+ w_1      = dexp(-e_c_lsda1/(gama * phi_3)) - 1.d0
+ a        = beta_rs(rs) /(gama * w_1)
+ g_at2    = 1.d0/(1.d0 + 4.d0 * a*t*t)**0.25d0
+ h1       = gama * phi_3 * dlog(1.d0 + w_1 * (1.d0 - g_at2))
+ ! interpolation function 
+
+ if(cst_1alph.gt.0.d0)then
+  fc_alpha = dexp(-c_1c * alpha * inv_1alph) 
+ else
+  fc_alpha = - d_c * dexp(c_2c * inv_1alph) 
+ endif
+ ! first part of the correlation energy 
+ e_c_1    = e_c_lsda1 + h1
+ 
+ dx_xi    =  0.5d0 * ( (1.d0+xi)**cst_43 + (1.d0 - xi)**cst_43)
+ gc_xi    = (1.d0 - 2.3631d0 * (dx_xi - 1.d0) ) * (1.d0 - xi**12.d0)
+ e_c_lsda0= - b_1c / (1.d0 + b_2c * rs**0.5d0 + b_3c * rs)
+ w_0      = dexp(-e_c_lsda0/b_1c) - 1.d0
+ beta_inf = 0.066725d0 * 0.1d0 / 0.1778d0
+ cx_xi    = -3.d0/(4.d0*pi) * (9.d0 * pi/4.d0)**cst_13 * dx_xi
+
+ x_inf   = 0.128026d0
+ f0       = -0.9d0
+ g_inf    = 1.d0/(1.d0 + 4.d0 * x_inf * s*s)**0.25d0
+ 
+ h0       = b_1c * dlog(1.d0 + w_0 * (1.d0 - g_inf)) 
+ e_c_0    = (e_c_lsda0 + h0) * gc_xi
+
+ ec_scan = e_c_1 + fc_alpha * (e_c_0 - e_c_1)
+end
+
+
+double precision function beta_rs(rs)
+ implicit none
+ double precision, intent(in) ::rs
+ beta_rs = 0.066725d0 * (1.d0 + 0.1d0 * rs)/(1.d0 + 0.1778d0 * rs)
+
+end
+
+
+double precision function step_f(x)
+ implicit none
+ double precision, intent(in) :: x
+ if(x.lt.0.d0)then
+  step_f = 0.d0
+ else
+  step_f = 1.d0 
+ endif
+end             
--- a/src/dft_utils_one_e/rho_ab_to_rho_tot.irp.f
+++ b/src/dft_utils_one_e/rho_ab_to_rho_tot.irp.f
@ -1,5 +1,10 @@
 subroutine rho_ab_to_rho_oc(rho_a,rho_b,rho_o,rho_c)
 implicit none
+ BEGIN_DOC
+! convert rho_alpha, rho_beta to rho_c, rho_o
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 double precision, intent(in)  :: rho_a,rho_b
 double precision, intent(out) :: rho_o,rho_c
 rho_c=rho_a+rho_b
@ -8,6 +13,11 @@ end

 subroutine rho_oc_to_rho_ab(rho_o,rho_c,rho_a,rho_b)
 implicit none
+ BEGIN_DOC
+! convert rho_c, rho_o to rho_alpha, rho_beta 
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 double precision, intent(in)  :: rho_o,rho_c
 double precision, intent(out) :: rho_a,rho_b
 rho_a= 0.5d0*(rho_c+rho_o)
@ -18,6 +28,13 @@ end

 subroutine grad_rho_ab_to_grad_rho_oc(grad_rho_a_2,grad_rho_b_2,grad_rho_a_b,grad_rho_o_2,grad_rho_c_2,grad_rho_o_c)
 implicit none
+ BEGIN_DOC
+! convert (grad_rho_a_2, grad_rho_b_2, grad_rho_a.grad_rho_b, ) 
+!
+! to      (grad_rho_c_2, grad_rho_o_2, grad_rho_o.grad_rho_c) 
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 double precision, intent(in)  :: grad_rho_a_2,grad_rho_b_2,grad_rho_a_b
 double precision, intent(out) :: grad_rho_o_2,grad_rho_c_2,grad_rho_o_c
 grad_rho_c_2 = grad_rho_a_2 + grad_rho_b_2 + 2d0*grad_rho_a_b
@ -28,6 +45,11 @@ end


 subroutine v_rho_ab_to_v_rho_oc(v_rho_a,v_rho_b,v_rho_o,v_rho_c)
+ BEGIN_DOC
+! convert v_rho_alpha, v_rho_beta to v_rho_c, v_rho_o
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 implicit none
 double precision, intent(in)  :: v_rho_a,v_rho_b
 double precision, intent(out) :: v_rho_o,v_rho_c
@ -37,6 +59,11 @@ end

 subroutine v_rho_oc_to_v_rho_ab(v_rho_o,v_rho_c,v_rho_a,v_rho_b)
 implicit none
+ BEGIN_DOC
+! convert v_rho_alpha, v_rho_beta  to v_rho_c, v_rho_o 
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 double precision, intent(in)  :: v_rho_o,v_rho_c
 double precision, intent(out) :: v_rho_a,v_rho_b
 v_rho_a = v_rho_c + v_rho_o
@ -47,6 +74,13 @@ end

 subroutine v_grad_rho_oc_to_v_grad_rho_ab(v_grad_rho_o_2,v_grad_rho_c_2,v_grad_rho_o_c,v_grad_rho_a_2,v_grad_rho_b_2,v_grad_rho_a_b)
 implicit none
+ BEGIN_DOC
+! convert  (v_grad_rho_c_2, v_grad_rho_o_2, v_grad_rho_o.grad_rho_c) 
+!
+! to       (v_grad_rho_a_2, v_grad_rho_b_2, v_grad_rho_a.grad_rho_b) 
+!
+! rho_c = total density, rho_o spin density
+ END_DOC
 double precision, intent(in)  :: v_grad_rho_o_2,v_grad_rho_c_2,v_grad_rho_o_c
 double precision, intent(out) :: v_grad_rho_a_2,v_grad_rho_b_2,v_grad_rho_a_b
 v_grad_rho_a_2 = v_grad_rho_o_2 + v_grad_rho_c_2 + v_grad_rho_o_c
--- a/src/dft_utils_one_e/routines_exc_sr_lda.irp.f
+++ b/src/dft_utils_one_e/routines_exc_sr_lda.irp.f
--- a/src/dft_utils_one_e/routines_exc_sr_pbe.irp.f
+++ b/src/dft_utils_one_e/routines_exc_sr_pbe.irp.f
@ -189,16 +189,27 @@ end
 subroutine ex_pbe_sr(mu,rho_a,rho_b,grd_rho_a_2,grd_rho_b_2,grd_rho_a_b,ex,vx_rho_a,vx_rho_b,vx_grd_rho_a_2,vx_grd_rho_b_2,vx_grd_rho_a_b)
 BEGIN_DOC
 !mu    = range separation parameter
+!
 !rho_a = density alpha
+!
 !rho_b = density beta
+!
 !grd_rho_a_2 = (gradient rho_a)^2
+!
 !grd_rho_b_2 = (gradient rho_b)^2
+!
 !grd_rho_a_b = (gradient rho_a).(gradient rho_b)
+!
 !ex = exchange energy density at the density and corresponding gradients of the density
+!
 !vx_rho_a = d ex / d rho_a
+!
 !vx_rho_b = d ex / d rho_b
+!
 !vx_grd_rho_a_2 = d ex / d grd_rho_a_2
+!
 !vx_grd_rho_b_2 = d ex / d grd_rho_b_2
+!
 !vx_grd_rho_a_b = d ex / d grd_rho_a_b
 END_DOC

@ -313,10 +324,15 @@ END_DOC
 subroutine ex_pbe_sr_only(mu,rho_a,rho_b,grd_rho_a_2,grd_rho_b_2,grd_rho_a_b,ex)
 BEGIN_DOC
 !rho_a = density alpha
+!
 !rho_b = density beta
+!
 !grd_rho_a_2 = (gradient rho_a)^2
+!
 !grd_rho_b_2 = (gradient rho_b)^2
+!
 !grd_rho_a_b = (gradient rho_a).(gradient rho_b)
+!
 !ex = exchange energy density at point r
 END_DOC

--- a/src/dft_utils_one_e/sr_exc.irp.f
+++ b/src/dft_utils_one_e/sr_exc.irp.f
@ -1,86 +0,0 @@
-
-
- BEGIN_PROVIDER[double precision, energy_sr_x_lda, (N_states) ]
-&BEGIN_PROVIDER[double precision, energy_sr_c_lda, (N_states) ]
- implicit none
- BEGIN_DOC
-! exchange/correlation energy with the short range lda functional
- END_DOC
- integer :: istate,i,j
- double precision :: r(3)
- double precision :: mu,weight
- double precision :: e_c,vc_a,vc_b,e_x,vx_a,vx_b
- double precision, allocatable :: rhoa(:),rhob(:)
- allocate(rhoa(N_states), rhob(N_states))
- energy_sr_x_lda = 0.d0
- energy_sr_c_lda = 0.d0
- do istate = 1, N_states
-  do i = 1, n_points_final_grid
-   r(1) = final_grid_points(1,i)
-   r(2) = final_grid_points(2,i)
-   r(3) = final_grid_points(3,i)
-   weight = final_weight_at_r_vector(i)
-   rhoa(istate) = one_e_dm_and_grad_alpha_in_r(4,i,istate)
-   rhob(istate) = one_e_dm_and_grad_beta_in_r(4,i,istate)
-   call ec_lda_sr(mu_erf_dft,rhoa(istate),rhob(istate),e_c,vc_a,vc_b)
-   call ex_lda_sr(mu_erf_dft,rhoa(istate),rhob(istate),e_x,vx_a,vx_b)
-   energy_sr_x_lda(istate) += weight * e_x
-   energy_sr_c_lda(istate) += weight * e_c
-  enddo
- enddo
-
- END_PROVIDER
-
- BEGIN_PROVIDER[double precision, energy_sr_x_pbe, (N_states) ]
-&BEGIN_PROVIDER[double precision, energy_sr_c_pbe, (N_states) ]
- implicit none
- BEGIN_DOC
-! exchange/correlation energy with the short range pbe functional
- END_DOC
- integer :: istate,i,j,m
- double precision :: r(3)
- double precision :: mu,weight
- double precision, allocatable :: ex(:), ec(:)
- double precision, allocatable :: rho_a(:),rho_b(:),grad_rho_a(:,:),grad_rho_b(:,:),grad_rho_a_2(:),grad_rho_b_2(:),grad_rho_a_b(:)
- double precision, allocatable :: contrib_grad_xa(:,:),contrib_grad_xb(:,:),contrib_grad_ca(:,:),contrib_grad_cb(:,:)
- double precision, allocatable :: vc_rho_a(:), vc_rho_b(:), vx_rho_a(:), vx_rho_b(:)
- double precision, allocatable :: vx_grad_rho_a_2(:), vx_grad_rho_b_2(:), vx_grad_rho_a_b(:), vc_grad_rho_a_2(:), vc_grad_rho_b_2(:), vc_grad_rho_a_b(:)
- allocate(vc_rho_a(N_states), vc_rho_b(N_states), vx_rho_a(N_states), vx_rho_b(N_states))
- allocate(vx_grad_rho_a_2(N_states), vx_grad_rho_b_2(N_states), vx_grad_rho_a_b(N_states), vc_grad_rho_a_2(N_states), vc_grad_rho_b_2(N_states), vc_grad_rho_a_b(N_states))
-
-
- allocate(rho_a(N_states), rho_b(N_states),grad_rho_a(3,N_states),grad_rho_b(3,N_states))
- allocate(grad_rho_a_2(N_states),grad_rho_b_2(N_states),grad_rho_a_b(N_states), ex(N_states), ec(N_states))
- energy_sr_x_pbe = 0.d0
- energy_sr_c_pbe = 0.d0
- do istate = 1, N_states
-  do i = 1, n_points_final_grid
-   r(1) = final_grid_points(1,i)
-   r(2) = final_grid_points(2,i)
-   r(3) = final_grid_points(3,i)
-   weight = final_weight_at_r_vector(i)
-   rho_a(istate) =  one_e_dm_and_grad_alpha_in_r(4,i,istate)
-   rho_b(istate) =  one_e_dm_and_grad_beta_in_r(4,i,istate)
-   grad_rho_a(1:3,istate) =  one_e_dm_and_grad_alpha_in_r(1:3,i,istate)
-   grad_rho_b(1:3,istate) =  one_e_dm_and_grad_beta_in_r(1:3,i,istate)
-   grad_rho_a_2 = 0.d0
-   grad_rho_b_2 = 0.d0
-   grad_rho_a_b = 0.d0
-   do m = 1, 3
-    grad_rho_a_2(istate) += grad_rho_a(m,istate) * grad_rho_a(m,istate)
-    grad_rho_b_2(istate) += grad_rho_b(m,istate) * grad_rho_b(m,istate)
-    grad_rho_a_b(istate) += grad_rho_a(m,istate) * grad_rho_b(m,istate)
-   enddo
-
-                             ! inputs
-   call GGA_sr_type_functionals(r,rho_a,rho_b,grad_rho_a_2,grad_rho_b_2,grad_rho_a_b,                 &  ! outputs exchange
-                             ex,vx_rho_a,vx_rho_b,vx_grad_rho_a_2,vx_grad_rho_b_2,vx_grad_rho_a_b, &  ! outputs correlation
-                             ec,vc_rho_a,vc_rho_b,vc_grad_rho_a_2,vc_grad_rho_b_2,vc_grad_rho_a_b  )
-   energy_sr_x_pbe += ex * weight
-   energy_sr_c_pbe += ec * weight
-  enddo
- enddo
-
-
-END_PROVIDER
-