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mirror of https://github.com/QuantumPackage/qp2.git synced 2024-12-22 03:23:29 +01:00
qp2/src/functionals/sr_lda.irp.f

202 lines
7.7 KiB
Fortran

BEGIN_PROVIDER[double precision, energy_x_sr_lda, (N_states) ]
implicit none
BEGIN_DOC
! exchange energy with the short range lda functional
END_DOC
integer :: istate,i,j
double precision :: r(3)
double precision :: mu,weight
double precision :: e_x,vx_a,vx_b
double precision, allocatable :: rhoa(:),rhob(:)
allocate(rhoa(N_states), rhob(N_states))
energy_x_sr_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)
double precision :: mu_local
mu_local = mu_of_r_dft(i)
call ex_lda_sr(mu_local,rhoa(istate),rhob(istate),e_x,vx_a,vx_b)
energy_x_sr_lda(istate) += weight * e_x
enddo
enddo
END_PROVIDER
BEGIN_PROVIDER[double precision, energy_c_sr_lda, (N_states) ]
implicit none
BEGIN_DOC
! exchange 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
double precision, allocatable :: rhoa(:),rhob(:)
allocate(rhoa(N_states), rhob(N_states))
energy_c_sr_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)
double precision :: mu_local
mu_local = mu_of_r_dft(i)
call ec_lda_sr(mu_local,rhoa(istate),rhob(istate),e_c,vc_a,vc_b)
energy_c_sr_lda(istate) += weight * e_c
enddo
enddo
END_PROVIDER
BEGIN_PROVIDER [double precision, potential_x_alpha_ao_sr_lda,(ao_num,ao_num,N_states)]
&BEGIN_PROVIDER [double precision, potential_x_beta_ao_sr_lda,(ao_num,ao_num,N_states)]
implicit none
BEGIN_DOC
! short range exchange alpha/beta potentials with lda functional on the |AO| basis
END_DOC
! Second dimension is given as ao_num * N_states so that Lapack does the loop over N_states.
integer :: istate
do istate = 1, N_states
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vx_alpha_lda_w,size(aos_sr_vx_alpha_lda_w,1),0.d0,&
potential_x_alpha_ao_sr_lda,size(potential_x_alpha_ao_sr_lda,1))
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vx_beta_lda_w(1,1,istate),size(aos_sr_vx_beta_lda_w,1),0.d0,&
potential_x_beta_ao_sr_lda(1,1,istate),size(potential_x_beta_ao_sr_lda,1))
enddo
END_PROVIDER
BEGIN_PROVIDER [double precision, potential_c_alpha_ao_sr_lda,(ao_num,ao_num,N_states)]
&BEGIN_PROVIDER [double precision, potential_c_beta_ao_sr_lda,(ao_num,ao_num,N_states)]
implicit none
BEGIN_DOC
! short range correlation alpha/beta potentials with lda functional on the |AO| basis
END_DOC
! Second dimension is given as ao_num * N_states so that Lapack does the loop over N_states.
integer :: istate
do istate = 1, N_states
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vc_alpha_lda_w(1,1,istate),size(aos_sr_vc_alpha_lda_w,1),0.d0,&
potential_c_alpha_ao_sr_lda(1,1,istate),size(potential_c_alpha_ao_sr_lda,1))
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vc_beta_lda_w(1,1,istate),size(aos_sr_vc_beta_lda_w,1),0.d0,&
potential_c_beta_ao_sr_lda(1,1,istate),size(potential_c_beta_ao_sr_lda,1))
enddo
END_PROVIDER
BEGIN_PROVIDER[double precision, aos_sr_vc_alpha_lda_w, (ao_num,n_points_final_grid,N_states)]
&BEGIN_PROVIDER[double precision, aos_sr_vc_beta_lda_w, (ao_num,n_points_final_grid,N_states)]
&BEGIN_PROVIDER[double precision, aos_sr_vx_alpha_lda_w, (ao_num,n_points_final_grid,N_states)]
&BEGIN_PROVIDER[double precision, aos_sr_vx_beta_lda_w, (ao_num,n_points_final_grid,N_states)]
implicit none
BEGIN_DOC
! aos_sr_vxc_alpha_lda_w(j,i) = ao_i(r_j) * (sr_v^x_alpha(r_j) + sr_v^c_alpha(r_j)) * W(r_j)
END_DOC
integer :: istate,i,j
double precision :: r(3)
double precision :: mu,weight
double precision :: e_c,sr_vc_a,sr_vc_b,e_x,sr_vx_a,sr_vx_b
double precision, allocatable :: rhoa(:),rhob(:)
allocate(rhoa(N_states), rhob(N_states))
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)
double precision :: mu_local
mu_local = mu_of_r_dft(i)
call ec_lda_sr(mu_local,rhoa(istate),rhob(istate),e_c,sr_vc_a,sr_vc_b)
call ex_lda_sr(mu_local,rhoa(istate),rhob(istate),e_x,sr_vx_a,sr_vx_b)
do j =1, ao_num
aos_sr_vc_alpha_lda_w(j,i,istate) = sr_vc_a * aos_in_r_array(j,i)*weight
aos_sr_vc_beta_lda_w(j,i,istate) = sr_vc_b * aos_in_r_array(j,i)*weight
aos_sr_vx_alpha_lda_w(j,i,istate) = sr_vx_a * aos_in_r_array(j,i)*weight
aos_sr_vx_beta_lda_w(j,i,istate) = sr_vx_b * aos_in_r_array(j,i)*weight
enddo
enddo
enddo
END_PROVIDER
BEGIN_PROVIDER[double precision, aos_sr_vxc_alpha_lda_w, (ao_num,n_points_final_grid,N_states)]
&BEGIN_PROVIDER[double precision, aos_sr_vxc_beta_lda_w, (ao_num,n_points_final_grid,N_states)]
implicit none
BEGIN_DOC
! aos_sr_vxc_alpha_lda_w(j,i) = ao_i(r_j) * (v^x_alpha(r_j) + v^c_alpha(r_j)) * W(r_j)
END_DOC
integer :: istate,i,j
double precision :: r(3)
double precision :: mu,weight
double precision :: e_c,sr_vc_a,sr_vc_b,e_x,sr_vx_a,sr_vx_b
double precision, allocatable :: rhoa(:),rhob(:)
allocate(rhoa(N_states), rhob(N_states))
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)
double precision :: mu_local
mu_local = mu_of_r_dft(i)
call ec_lda_sr(mu_local,rhoa(istate),rhob(istate),e_c,sr_vc_a,sr_vc_b)
call ex_lda_sr(mu_local,rhoa(istate),rhob(istate),e_x,sr_vx_a,sr_vx_b)
do j =1, ao_num
aos_sr_vxc_alpha_lda_w(j,i,istate) = (sr_vc_a + sr_vx_a) * aos_in_r_array(j,i)*weight
aos_sr_vxc_beta_lda_w(j,i,istate) = (sr_vc_b + sr_vx_b) * aos_in_r_array(j,i)*weight
enddo
enddo
enddo
END_PROVIDER
BEGIN_PROVIDER [double precision, potential_xc_alpha_ao_sr_lda,(ao_num,ao_num,N_states)]
&BEGIN_PROVIDER [double precision, potential_xc_beta_ao_sr_lda ,(ao_num,ao_num,N_states)]
implicit none
BEGIN_DOC
! short range exchange/correlation alpha/beta potentials with lda functional on the AO basis
END_DOC
integer :: istate
do istate = 1, N_states
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vxc_alpha_lda_w(1,1,istate),size(aos_sr_vxc_alpha_lda_w,1),0.d0,&
potential_xc_alpha_ao_sr_lda(1,1,istate),size(potential_xc_alpha_ao_sr_lda,1))
call dgemm('N','T',ao_num,ao_num,n_points_final_grid,1.d0, &
aos_in_r_array,size(aos_in_r_array,1), &
aos_sr_vxc_beta_lda_w(1,1,istate),size(aos_sr_vxc_beta_lda_w,1),0.d0,&
potential_xc_beta_ao_sr_lda(1,1,istate),size(potential_xc_beta_ao_sr_lda,1))
enddo
END_PROVIDER