Manu: started polishing the exact theory part
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@ -94,7 +94,7 @@
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\newcommand{\beq}{\begin{eqnarray}}
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\newcommand{\beq}{\begin{eqnarray}}
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\newcommand{\eeq}{\nonumber\end{eqnarray}}
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\newcommand{\eeq}{\nonumber\end{eqnarray}}
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\newcommand{\bmk}{\bm{\kappa}} % orbital rotation vector
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\newcommand{\bmk}{\bm{\kappa}} % orbital rotation vector
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\newcommand{\bmg}{\bm{\gamma}} % orbital rotation vector
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\newcommand{\bmg}{\bm{\Gamma}} % orbital rotation vector
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\newcommand{\bfx}{\bf{x}}
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\newcommand{\bfx}{\bf{x}}
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\newcommand{\bfr}{\bf{r}}
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\newcommand{\bfr}{\bf{r}}
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%%%%
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%%%%
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@ -173,28 +173,82 @@ Atomic units are used throughout.
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\label{sec:geKS}
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\label{sec:geKS}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\alert{Manu, you might want to add general details about the eDFT here.}
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Since Hartree and exchange energy contributions cannot be separated in
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\manu{Yes. Copy paste from the SI. Will polish the all thing.}
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the one-dimensional case, we introduce in the following an alternative
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formulation of KS-eDFT where, in complete analogy with the generalized
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KS scheme, a HF-like Hartree-exchange energy is employed. This
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formulation is in principle exact and applicable to higher dimensions.
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Let us start from the analog for ensembles of Levy's universal
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functional,
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\beq
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F^{\bw}[n]&=&
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\underset{\hat{\gamma}^{{\bw}}\rightarrow n}{\rm min}\left\{{\rm
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Tr}\left[\hat{\gamma}^{{\bw}}\left(\hat{T}+\hat{W}_{\rm
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ee}\right)\right]\right\}
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\eeq
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where ${\rm
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Tr}$ denotes the trace. The minimization over trial ensemble density matrix operators
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$\hat{\gamma}^{{\bw}}=\sum^M_{K=0}w^{(K)}\vert\Psi^{(K)}\rangle\langle\Psi^{(K)}\vert$
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is performed under the following density constraint:
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\beq
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{\rm
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Tr}\left[\hat{\gamma}^{{\bw}}\hat{n}(\br)\right]=\sum^M_{K=0}w^{(K)}n_{\Psi^{(K)}}(\br)=n(\br),
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\eeq
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where $\hat{n}(\br)$ is the density operator, $n_{\Psi}$ denotes the
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density of wavefunction $\Psi$, and
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$\bw\equiv\left(w^{(1)},w^{(2)},\ldots\right)$ is the collection of
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(decreasing) ensemble weights assigned to the excited states. Note that
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$w^{(0)}=1-\sum^M_{K>0}w^{(K)}\geq 0$.
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\beq
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F^{\bw=0}[n]=F[n]=\underset{\Psi\rightarrow n}{\rm min}
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\bra{\Psi}\hat{T}+\hat{W}_{\rm
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ee}\ket{\Psi}
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\eeq
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\beq
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F[n]&=&
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\underset{\Phi\rightarrow n}{\rm min}
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\bra{\Phi}\hat{T}+\hat{W}_{\rm
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ee}\ket{\Phi}+\overline{E}_{\rm c}[n]
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\nonumber\\
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&=&
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\underset{\Phi\rightarrow n}{\rm min}
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\left\{{\rm
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Tr}\left[\bmg^\Phi{\bm t}\right]+W_{\rm
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HF}\left[{\bmg}^{\Phi}\right]\right\}+
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\overline{E}_{\rm c}[n]
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\eeq
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where ${\bm t}$ is the matrix representation of the one-electron kinetic
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energy operator, $\bmg^\Phi$ is the one-electron reduced density
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matrix (just referred to as density matrix in the following) of $\Phi$,
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and
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\beq
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W_{\rm
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HF}\left[{\bmg}\right]\equiv\frac{1}{2} \Tr(\bmg \, \bG \, \bmg)
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\eeq
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is the conventional density-matrix functional HF Hartree-exchange
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energy. By analogy with Eq.~(\ref{}),
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\beq
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\beq
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F^{\bw}_{\rm HF}[n]&=&
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F^{\bw}_{\rm HF}[n]&=&
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\underset{\hat{\gamma}^{{\bw}}\rightarrow n}{\rm min}\left\{{\rm
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\underset{\hat{\Gamma}^{{\bw}}\rightarrow n}{\rm min}\left\{{\rm
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Tr}\left[\hat{\gamma}^{{\bw}}\hat{T}\right]+W_{\rm
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Tr}\left[\hat{\Gamma}^{{\bw}}\hat{T}\right]+W_{\rm
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HF}\left[{\bmg}^{\bw}\right]\right\}
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HF}\left[{\bmg}^{\bw}\right]\right\}
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\nonumber\\
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\nonumber\\
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&=&{\rm
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&=&{\rm
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Tr}\left[\hat{\gamma}^{{\bw}}[n]\hat{T}\right]+W_{\rm
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Tr}\left[\hat{\Gamma}^{{\bw}}[n]\hat{T}\right]+W_{\rm
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HF}\left[{\bmg}^{\bw}[n]\right]
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HF}\left[{\bmg}^{\bw}[n]\right]
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\eeq
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\eeq
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where
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where
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$\hat{\gamma}^{{\bw}}=\sum^M_{K=0}w^{(K)}\vert\Phi^{(K)}\rangle\langle\Phi^{(K)}\vert=\sum^M_{K=0}w^{(K)}\hat{\gamma}^{(K)}$ is an ensemble density matrix operator constructed
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$\hat{\Gamma}^{{\bw}}=\sum^M_{K=0}w^{(K)}\vert\Phi^{(K)}\rangle\langle\Phi^{(K)}\vert=\sum^M_{K=0}w^{(K)}\hat{\Gamma}^{(K)}$ is an ensemble density matrix operator constructed
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from Slater determinants, the ensemble 1RDM elements are $\gamma_{pq}^{\bw}={\rm
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from Slater determinants, the ensemble 1RDM elements are $\Gamma_{pq}^{\bw}={\rm
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Tr}\left[\hat{\gamma}^{{\bw}}\hat{a}^\dagger_p\hat{a}_q\right]$,
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Tr}\left[\hat{\Gamma}^{{\bw}}\hat{a}^\dagger_p\hat{a}_q\right]$,
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and $W_{\rm
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and $W_{\rm
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HF}\left[{\bmg}\right]=\frac{1}{2}\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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HF}\left[{\bmg}\right]=\frac{1}{2}\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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\varphi_r\varphi_s\rangle
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\varphi_r\varphi_s\rangle
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%\times
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%\times
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\gamma_{pr}\gamma_{qs}$.\\
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\Gamma_{pr}\Gamma_{qs}$.\\
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In-principle-exact decomposition:
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In-principle-exact decomposition:
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@ -231,17 +285,17 @@ Hx}[n]$ and $E^{{\bw}}_{\rm c}[n]$ functionals. Am I right ?}
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Variational expression for the ensemble energy:
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Variational expression for the ensemble energy:
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\beq
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\beq
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E^{{\bw}}=\underset{\hat{\gamma}^{{\bw}}}{\rm min}\Big\{
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E^{{\bw}}=\underset{\hat{\Gamma}^{{\bw}}}{\rm min}\Big\{
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&&{\rm
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&&{\rm
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Tr}\left[\hat{\gamma}^{{\bw}}\hat{T}\right]+W_{\rm
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Tr}\left[\hat{\Gamma}^{{\bw}}\hat{T}\right]+W_{\rm
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HF}\left[{\bmg}^{\bw}\right]
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HF}\left[{\bmg}^{\bw}\right]
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+
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+
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\overline{E}^{{\bw}}_{\rm
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\overline{E}^{{\bw}}_{\rm
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Hxc}\left[n_{\hat{\gamma}^{{\bw}}}\right]
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Hxc}\left[n_{\hat{\Gamma}^{{\bw}}}\right]
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%+E^{{\bw}}_{\rm c}\left[n_{\hat{\gamma}^{{\bw}}}\right]
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%+E^{{\bw}}_{\rm c}\left[n_{\hat{\Gamma}^{{\bw}}}\right]
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\nonumber\\
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\nonumber\\
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&&
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&&
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+\int d{\br}\;v_{\rm ext}({\bfr})n_{\hat{\gamma}^{{\bw}}}({\bfr})
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+\int d{\br}\;v_{\rm ext}({\bfr})n_{\hat{\Gamma}^{{\bw}}}({\bfr})
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\Big\}
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\Big\}
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\eeq
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\eeq
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@ -258,7 +312,7 @@ n({\br})}\left.\dfrac{\partial n^{{\bw}}({\bmk},{\br})}{\partial \kappa_{lm}}
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\eeq
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\eeq
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where
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where
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\beq
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\beq
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n^{{\bw}}({\bmk},{\br})=\sum_\sigma\sum_{pq}\varphi_p({\bmk},{\bfx})\varphi_q({\bmk},{\bfx})\gamma_{pq}^{\bw}
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n^{{\bw}}({\bmk},{\br})=\sum_\sigma\sum_{pq}\varphi_p({\bmk},{\bfx})\varphi_q({\bmk},{\bfx})\Gamma_{pq}^{\bw}
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\eeq
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\eeq
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thus leading to
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thus leading to
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\beq
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\beq
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@ -266,7 +320,7 @@ thus leading to
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\overline{E}^{{\bw}}_{\rm Hxc}\left[n^{{\bw}}({\bmk})\right]
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\overline{E}^{{\bw}}_{\rm Hxc}\left[n^{{\bw}}({\bmk})\right]
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}{\partial \kappa_{lm}}
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}{\partial \kappa_{lm}}
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\right|_{{\bmk}=0}=
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\right|_{{\bmk}=0}=
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\sum_{pq}\gamma_{pq}^{\bw}
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\sum_{pq}\Gamma_{pq}^{\bw}
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\nonumber\\
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\nonumber\\
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&&\times\left.\dfrac{\partial}
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&&\times\left.\dfrac{\partial}
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{\partial \kappa_{lm}}
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{\partial \kappa_{lm}}
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@ -281,7 +335,7 @@ In conclusion, the minimizing canonical orbitals fulfill the following
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hybrid HF/GOK-DFT equation,
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hybrid HF/GOK-DFT equation,
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\beq
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\beq
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&&\left(-\frac{\nabla_{\bfr}^2}{2}+v_{\rm
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&&\left(-\frac{\nabla_{\bfr}^2}{2}+v_{\rm
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ext}({\bfr})+\hat{u}_{\rm HF}\left[\gamma^{\bw}\right]
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ext}({\bfr})+\hat{u}_{\rm HF}\left[\Gamma^{\bw}\right]
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+\dfrac{\delta \overline{E}^{{\bw}}_{\rm Hxc}\left[n^{{\bw}}\right]}{\delta
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+\dfrac{\delta \overline{E}^{{\bw}}_{\rm Hxc}\left[n^{{\bw}}\right]}{\delta
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n({\br})}\right)\varphi^{{\bw}}_p({\bfx})
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n({\br})}\right)\varphi^{{\bw}}_p({\bfx})
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\nonumber
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\nonumber
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@ -290,8 +344,8 @@ n({\br})}\right)\varphi^{{\bw}}_p({\bfx})
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\eeq
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\eeq
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Since $\partial \gamma_{pq}^{\bw}/\partial
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Since $\partial \Gamma_{pq}^{\bw}/\partial
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w^{(I)}=\gamma_{pq}^{(I)}-\gamma_{pq}^{(0)}$, it comes
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w^{(I)}=\Gamma_{pq}^{(I)}-\Gamma_{pq}^{(0)}$, it comes
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\manu{just for me ...
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\manu{just for me ...
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\beq
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\beq
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@ -299,25 +353,25 @@ w^{(I)}=\gamma_{pq}^{(I)}-\gamma_{pq}^{(0)}$, it comes
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\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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\varphi_r\varphi_s\rangle
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\varphi_r\varphi_s\rangle
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%\times
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%\times
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\left(\gamma_{pr}^{(I)}-\gamma_{pr}^{(0)}\right)\gamma^{\bw}_{qs}
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\left(\Gamma_{pr}^{(I)}-\Gamma_{pr}^{(0)}\right)\Gamma^{\bw}_{qs}
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\nonumber\\
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\nonumber\\
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&&+\dfrac{1}{2}\sum_{pqrs}\langle \varphi_q\varphi_p\vert\vert
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&&+\dfrac{1}{2}\sum_{pqrs}\langle \varphi_q\varphi_p\vert\vert
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\varphi_s\varphi_r\rangle
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\varphi_s\varphi_r\rangle
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%\times
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%\times
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\gamma^{\bw}_{pr}\left(\gamma_{qs}^{(I)}-\gamma_{qs}^{(0)}\right)
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\Gamma^{\bw}_{pr}\left(\Gamma_{qs}^{(I)}-\Gamma_{qs}^{(0)}\right)
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\nonumber\\
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\nonumber\\
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&&=
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&&=
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\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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\sum_{pqrs}\langle \varphi_p\varphi_q\vert\vert
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\varphi_r\varphi_s\rangle
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\varphi_r\varphi_s\rangle
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%\times
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%\times
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\left(\gamma_{pr}^{(I)}-\gamma_{pr}^{(0)}\right)\gamma^{\bw}_{qs}
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\left(\Gamma_{pr}^{(I)}-\Gamma_{pr}^{(0)}\right)\Gamma^{\bw}_{qs}
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\nonumber\\
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\nonumber\\
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&&=
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&&=
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\sum_{pr}\left[\hat{u}_{\rm HF}\left[\gamma^{\bw}\right]\right]_{pr}\left(\gamma_{pr}^{(I)}-\gamma_{pr}^{(0)}\right)
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\sum_{pr}\left[\hat{u}_{\rm HF}\left[\Gamma^{\bw}\right]\right]_{pr}\left(\Gamma_{pr}^{(I)}-\Gamma_{pr}^{(0)}\right)
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\nonumber\\
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\nonumber\\
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&&=
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&&=
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\sum_p\left[\hat{u}_{\rm
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\sum_p\left[\hat{u}_{\rm
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HF}\left[\gamma^{\bw}\right]\right]_{pp}\left(\nu_p^{(I)}-\nu_p^{(0)}\right)
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HF}\left[\Gamma^{\bw}\right]\right]_{pp}\left(\nu_p^{(I)}-\nu_p^{(0)}\right)
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\eeq
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\eeq
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}
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}
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