mirror of
https://github.com/LCPQ/quantum_package
synced 2024-11-19 04:22:36 +01:00
173 lines
5.6 KiB
Fortran
173 lines
5.6 KiB
Fortran
BEGIN_PROVIDER [ double precision, ao_ortho_mono_elec_integral_dressing, (ao_num_align,ao_num) ]
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implicit none
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BEGIN_DOC
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! Dressing of the core hamiltonian in the orthogonal AO basis set
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END_DOC
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integer :: i,j,k
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integer :: mu, nu, lambda, A
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double precision :: tmp
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ao_ortho_mono_elec_integral_dressing = 0.d0
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i = idx_dressing
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do mu=1,ao_num
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if (dabs(mo_coef_in_ao_ortho_basis(mu,i)) > 1.d-5) then
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do A=1,nucl_num
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tmp = 0.d0
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do nu=1,ao_num
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tmp += AO_orthoSlaOverlap_matrix(nu,A) * ao_ortho_mono_elec_integral(mu,nu)
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enddo
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ao_ortho_mono_elec_integral_dressing(mu,mu) += cusp_C(A,i) * (AO_orthoSlaH_matrix(mu,A) - tmp)
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enddo
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ao_ortho_mono_elec_integral_dressing(mu,mu) *= 1.d0/mo_coef_in_ao_ortho_basis(mu,i)
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endif
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enddo
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END_PROVIDER
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BEGIN_PROVIDER [ double precision, ao_ortho_mono_elec_integral, (ao_num_align, ao_num) ]
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implicit none
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BEGIN_DOC
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! h core in orthogonal AO basis
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END_DOC
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double precision, allocatable :: T(:,:)
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allocate(T(ao_num,ao_num))
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call dgemm('T','N',ao_num,ao_num,ao_num,1.d0, &
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ao_ortho_canonical_coef, size(ao_ortho_canonical_coef,1), &
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ao_mono_elec_integral, size(ao_mono_elec_integral,1), &
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0.d0, T, size(T,1))
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call dgemm('N','N',ao_num,ao_num,ao_num,1.d0, &
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T, size(T,1), &
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ao_ortho_canonical_coef, size(ao_ortho_canonical_coef,1), &
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0.d0, ao_ortho_mono_elec_integral, size(ao_ortho_mono_elec_integral,1))
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deallocate(T)
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END_PROVIDER
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BEGIN_PROVIDER [ double precision, ao_mono_elec_integral_dressing, (ao_num,ao_num) ]
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implicit none
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BEGIN_DOC
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! Dressing of the core hamiltonian in the AO basis set
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END_DOC
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call ao_ortho_cano_to_ao(ao_ortho_mono_elec_integral_dressing,size(ao_ortho_mono_elec_integral_dressing,1),&
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ao_mono_elec_integral_dressing,size(ao_mono_elec_integral_dressing,1))
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END_PROVIDER
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BEGIN_PROVIDER [ double precision, mo_mono_elec_integral_dressing, (mo_tot_num_align,mo_tot_num) ]
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implicit none
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BEGIN_DOC
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! Dressing of the core hamiltonian in the MO basis set
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END_DOC
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call ao_to_mo(ao_mono_elec_integral_dressing,size(ao_mono_elec_integral_dressing,1),&
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mo_mono_elec_integral_dressing,size(mo_mono_elec_integral_dressing,1))
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END_PROVIDER
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BEGIN_PROVIDER [ integer, idx_dressing ]
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implicit none
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BEGIN_DOC
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! Index of the MO which is being dressed
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END_DOC
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idx_dressing = 1
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END_PROVIDER
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BEGIN_PROVIDER [ double precision, cusp_corrected_mos, (ao_num_align,mo_tot_num) ]
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implicit none
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BEGIN_DOC
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! Dressing core hamiltonian in the AO basis set
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END_DOC
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integer :: i,j
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double precision, allocatable :: F(:,:), M(:,:)
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allocate(F(mo_tot_num_align,mo_tot_num),M(ao_num,mo_tot_num))
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logical :: oneshot
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! oneshot = .True.
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oneshot = .False.
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if (oneshot) then
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cusp_corrected_mos(1:ao_num,1:mo_tot_num) = mo_coef(1:ao_num,1:mo_tot_num)
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slater_coef(1:nucl_num,1:mo_tot_num) = cusp_C(1:nucl_num,1:mo_tot_num)
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return
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else
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do idx_dressing=1,mo_tot_num
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if (idx_dressing>1) then
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TOUCH idx_dressing
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endif
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do j=1,mo_tot_num
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do i=1,mo_tot_num
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F(i,j) = Fock_matrix_mo(i,j)
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enddo
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enddo
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do j=1,mo_tot_num
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do i=1,ao_num
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M(i,j) = mo_coef(i,j)
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enddo
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enddo
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integer :: it
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do it=1,128
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! print *, 'X', ao_ortho_canonical_coef(1:ao_num,1:ao_num)
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! print *, 'C', mo_coef(1:ao_num,1:mo_tot_num)
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! print *, 'Cp', mo_coef_in_ao_ortho_basis(1:ao_num,1:mo_tot_num)
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! print *, 'cAi', cusp_C(1:nucl_num,1:mo_tot_num)
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! print *, 'FmuA', AO_orthoSlaH_matrix(1:ao_num,1:nucl_num)
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! print *, 'Fock:', Fock_matrix_ao(1:ao_num,1:ao_num)
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! print *, 'Diag Dressing:', ao_ortho_mono_elec_integral_dressing(1:ao_num,1:ao_num)
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! print *, 'Dressing:', ao_mono_elec_integral_dressing(1:ao_num,1:ao_num)
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! print *, 'Dressed Fock:', Fock_matrix_ao(1:ao_num,1:ao_num) + ao_mono_elec_integral_dressing(1:ao_num,1:ao_num)
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! print *, 'AO_orthoSlaOverlap_matrix', AO_orthoSlaOverlap_matrix(1:ao_num,1:nucl_num)
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! print *, 'AO_orthoSlaH_matrix', AO_orthoSlaH_matrix(1:ao_num,1:nucl_num)
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! print *, 'ao_ortho_mono_elec_integral', ao_ortho_mono_elec_integral(1:ao_num,1:ao_num)
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! print *, 'Fock MO:', Fock_matrix_mo(1:mo_tot_num,1:mo_tot_num)
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do j=1,mo_tot_num
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do i=1,mo_tot_num
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Fock_matrix_mo(i,j) += mo_mono_elec_integral_dressing(i,j)
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enddo
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enddo
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do i=1,mo_tot_num
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Fock_matrix_diag_mo(i) = Fock_matrix_mo(i,i)
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enddo
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! print *, 'Dressed Fock MO:', Fock_matrix_mo(1:mo_tot_num,1:mo_tot_num)
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double precision :: conv
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conv = 0.d0
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do j=1,mo_tot_num
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do i=1,mo_tot_num
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if (i==j) cycle
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conv = max(conv,Fock_matrix_mo(i,j))
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enddo
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enddo
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TOUCH Fock_matrix_mo Fock_matrix_diag_mo
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mo_coef(1:ao_num,1:mo_tot_num) = eigenvectors_fock_matrix_mo(1:ao_num,1:mo_tot_num)
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TOUCH mo_coef
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!print *, 'C', mo_coef(1:ao_num,1:mo_tot_num)
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!print *, '-----'
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print *, idx_dressing, it, real(mo_coef(1,idx_dressing)), real(conv)
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if (conv < 1.d-5) exit
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!stop
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enddo
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cusp_corrected_mos(1:ao_num,idx_dressing) = mo_coef(1:ao_num,idx_dressing)
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slater_coef(1:nucl_num,idx_dressing) = cusp_C(1:nucl_num,idx_dressing)
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enddo
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idx_dressing = 1
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mo_coef(1:ao_num,1:mo_tot_num) = M(1:ao_num,1:mo_tot_num)
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soft_TOUCH mo_coef idx_dressing slater_coef
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endif
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END_PROVIDER
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