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mirror of https://github.com/QuantumPackage/qp2.git synced 2024-12-22 19:43:32 +01:00

working on scan

This commit is contained in:
Emmanuel Giner LCT 2019-06-17 11:37:15 +02:00
parent a6bff0220f
commit 7bb0f7d963

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@ -37,7 +37,8 @@ double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
gama = 0.031091d0 gama = 0.031091d0
! correlation energy lsda1 ! correlation energy lsda1
call ec_only_lda_sr(0.d0,nup,ndo,e_c_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 xi = spin_d/rho
rs = (cst_43 * pi * rho)**(-cst_13) rs = (cst_43 * pi * rho)**(-cst_13)
s = drho/( 2.d0 * cst_3pi2**(cst_13) * rho**cst_43 ) s = drho/( 2.d0 * cst_3pi2**(cst_13) * rho**cst_43 )
@ -61,7 +62,11 @@ double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
g_at2 = 1.d0/(1.d0 + 4.d0 * a*t*t)**0.25d0 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)) h1 = gama * phi_3 * dlog(1.d0 + w_1 * (1.d0 - g_at2))
! interpolation function ! 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) 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 ! first part of the correlation energy
e_c_1 = e_c_lsda1 + h1 e_c_1 = e_c_lsda1 + h1
@ -82,19 +87,107 @@ double precision function ec_scan(rho_a,rho_b,tau,grad_rho_2)
ec_scan = e_c_1 + fc_alpha * (e_c_0 - e_c_1) ec_scan = e_c_1 + fc_alpha * (e_c_0 - e_c_1)
end 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) double precision function beta_rs(rs)
implicit none implicit none
double precision, intent(in) ::rs double precision, intent(in) ::rs
beta_rs(rs) = 0.066725d0 * (1.d0 + 0.1d0 * rs)/(1.d0 + 0.1778d0 * rs) beta_rs(rs) = 0.066725d0 * (1.d0 + 0.1d0 * rs)/(1.d0 + 0.1778d0 * rs)
!beta_rs(rs) = 0.066725d0
end end
double precision function ec_scan_print(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_print = 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))
print*,'w_1 g_at2 '
print*, w_1 , g_at2
print*,'gama phi_3 1.d0 + w_1 * (1.d0 - g_at2)'
print*, gama , phi_3 , 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
print*,'e_c_lsda1 h1 '
print*, 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_print = e_c_1 + fc_alpha * (e_c_0 - e_c_1)
write(*,*)' e_c_1 , fc_alpha , e_c_0 '
write(*,*) e_c_1 , fc_alpha , e_c_0
end