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BF_GS_VTZ.pdf
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BF_GS_VTZ.pdf
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BSE-PES.tex
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BSE-PES.tex
@ -315,9 +315,9 @@ the $(\bA{\IS},\bB{\IS})$ BSE matrix elements read:
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\begin{subequations}
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\begin{subequations}
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\label{eq:LR_BSE}
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\label{eq:LR_BSE}
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\begin{align}
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\begin{align}
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\ABSE{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eGW{a} - \eGW{i}) + \IS \left[ \ERI{ia}{jb} - \W{ij,ab}{\IS} \right],
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\ABSE{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eGW{a} - \eGW{i}) + \IS \qty[ 2 \ERI{ia}{jb} - \W{ij,ab}{\IS} ],
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\\
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\\
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\BBSE{ia,jb}{\IS} & = \lambda \left[ \ERI{ia}{bj} - \W{ib,aj}{\IS} \right],
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\BBSE{ia,jb}{\IS} & = \lambda \qty[ 2 \ERI{ia}{bj} - \W{ib,aj}{\IS} ],
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\end{align}
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\end{align}
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\end{subequations}
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\end{subequations}
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where $\eGW{p}$ are the $GW$ quasiparticle energies.
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where $\eGW{p}$ are the $GW$ quasiparticle energies.
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@ -333,22 +333,22 @@ In the standard BSE approach, the screened Coulomb potential $W^{\lambda}$ is bu
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with $\epsilon_{\lambda}$ the dielectric function at coupling constant $\lambda$ and $\chi_{0}$ the non-interacting polarizability. In the occupied-to-virtual molecular orbitals product basis, the spectral representation of $W^{\lambda}$ can be written as follows in the case of real molecular orbitals: \cite{complexw}
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with $\epsilon_{\lambda}$ the dielectric function at coupling constant $\lambda$ and $\chi_{0}$ the non-interacting polarizability. In the occupied-to-virtual molecular orbitals product basis, the spectral representation of $W^{\lambda}$ can be written as follows in the case of real molecular orbitals: \cite{complexw}
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\begin{multline}
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\begin{multline}
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\label{eq:W}
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\label{eq:W}
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\W{ij,ab}{\IS}(\omega) = \textcolor{red}{\sout{2}} \ERI{ij}{ab} + \sum_m^{\Nocc \Nvir} \sERI{ij}{m} \sERI{ab}{m}
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\W{ij,ab}{\IS}(\omega) = \ERI{ij}{ab} + 2 \sum_m^{\Nocc \Nvir} \sERI{ij}{m} \sERI{ab}{m}
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\\
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\\
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\times \qty(\frac{1}{\omega - \OmRPA{m}{\IS} + i \eta} \textcolor{red}{-} \frac{1}{\omega + \OmRPA{m}{\IS} - i \eta})
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\times \qty(\frac{1}{\omega - \OmRPA{m}{\IS} + i \eta} - \frac{1}{\omega + \OmRPA{m}{\IS} - i \eta}),
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\end{multline}
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\end{multline}
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where the \xavier{ \sout{screened two-electron integrals} spectral weights} $\sERI{pq}{m}$ at coupling strength $\lambda$ read:
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where the spectral weights at coupling strength $\lambda$ read
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\begin{equation}
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\begin{equation}
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\sERI{pq}{m} = \sum_i^{\Nocc} \sum_a^{\Nvir} \ERI{pq}{ia} (\bX{\IS}_m + \bY{\IS}_m)_{ia}
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\sERI{pq}{m} = \sum_i^{\Nocc} \sum_a^{\Nvir} \ERI{pq}{ia} (\bX{\IS}_m + \bY{\IS}_m)_{ia}.
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\end{equation}
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\end{equation}
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In Eq.~\eqref{eq:W}, $\eta$ is a positive infinitesimal, and $\OmRPA{m}{\IS}$ are the direct (\ie, without exchange) RPA neutral excitation energies computed by solving the linear eigenvalue problem \eqref{eq:LR} with the following matrix elements
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In Eq.~\eqref{eq:W}, $\eta$ is a positive infinitesimal, and $\OmRPA{m}{\IS}$ are the direct (\ie, without exchange) RPA neutral excitation energies computed by solving the linear eigenvalue problem \eqref{eq:LR} with the following matrix elements
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\begin{subequations}
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\begin{subequations}
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\begin{align}
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\begin{align}
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\label{eq:LR_RPA}
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\label{eq:LR_RPA}
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\ARPA{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eHF{a} - \eHF{i}) + \IS \ERI{ia}{jb},
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\ARPA{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eHF{a} - \eHF{i}) + 2 \IS \ERI{ia}{jb},
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\\
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\\
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\BRPA{ia,jb}{\IS} & = \IS \ERI{ia}{bj},
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\BRPA{ia,jb}{\IS} & = 2 \IS \ERI{ia}{bj},
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\end{align}
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\end{align}
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\end{subequations}
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\end{subequations}
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where $\eHF{p}$ are the HF orbital energies.
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where $\eHF{p}$ are the HF orbital energies.
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@ -359,15 +359,13 @@ so that $W^{\lambda}$ reduces to the bare Coulomb potential. In that limit, t
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\begin{subequations}
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\begin{subequations}
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\begin{align}
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\begin{align}
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\label{eq:LR_RPAx}
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\label{eq:LR_RPAx}
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\ARPAx{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eHF{a} - \eHF{i}) + \IS \left[ \ERI{ia}{jb} - \ERI{ij}{ab} \right],
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\ARPAx{ia,jb}{\IS} & = \delta_{ij} \delta_{ab} (\eHF{a} - \eHF{i}) + \IS \qty[ 2 \ERI{ia}{jb} - \ERI{ij}{ab} ],
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\\
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\\
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\BRPAx{ia,jb}{\IS} & = \IS \left[ \ERI{ia}{bj} - \ERI{ib}{aj} \right].
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\BRPAx{ia,jb}{\IS} & = \IS \qty[ 2 \ERI{ia}{bj} - \ERI{ib}{aj} ].
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\end{align}
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\end{align}
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\end{subequations}
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\end{subequations}
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%This allows to understand that the strength parameter $\lambda$ enters twice in the $\lambda W^{\lambda}$ contribution, one time to renormalize the screening efficiency, and a second time to renormalize the direct electron-hole interaction.
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%This allows to understand that the strength parameter $\lambda$ enters twice in the $\lambda W^{\lambda}$ contribution, one time to renormalize the screening efficiency, and a second time to renormalize the direct electron-hole interaction.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%\subsection{Ground-state BSE energy}
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%\subsection{Ground-state BSE energy}
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%\label{sec:BSE_energy}
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%\label{sec:BSE_energy}
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@ -564,9 +562,9 @@ Note that these irregularities would be genuine discontinuities in the case of {
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%%% FIG 2 %%%
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%%% FIG 2 %%%
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\begin{figure*}
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\begin{figure*}
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\includegraphics[height=0.35\linewidth]{LiF_GS_VQZ}
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\includegraphics[height=0.35\linewidth]{LiF_GS_VQZ}
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\includegraphics[height=0.35\linewidth]{HCl_GS_VTZ}
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\includegraphics[height=0.35\linewidth]{HCl_GS_VQZ}
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\caption{
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\caption{
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Ground-state PES of \ce{LiF} (left) and \ce{HCl} (right) around their respective equilibrium geometry obtained at various levels of theory with the \titou{cc-pVQZ} basis set.
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Ground-state PES of \ce{LiF} (left) and \ce{HCl} (right) around their respective equilibrium geometry obtained at various levels of theory with the cc-pVQZ basis set.
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Additional graphs for other basis sets and within the frozen-core approximation can be found in the {\SI}.
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Additional graphs for other basis sets and within the frozen-core approximation can be found in the {\SI}.
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\label{fig:PES-LiF-HCl}
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\label{fig:PES-LiF-HCl}
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}
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}
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@ -595,9 +593,9 @@ However, BSE@{\GOWO}@HF is the closest to the CC3 curve
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%%% FIG 4 %%%
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%%% FIG 4 %%%
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\begin{figure}
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\begin{figure}
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\includegraphics[width=\linewidth]{F2_GS_VTZ}
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\includegraphics[width=\linewidth]{F2_GS_VQZ}
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\caption{
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\caption{
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Ground-state PES of \ce{F2} around its equilibrium geometry obtained at various levels of theory with the \titou{cc-pVQZ} basis set.
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Ground-state PES of \ce{F2} around its equilibrium geometry obtained at various levels of theory with the cc-pVQZ basis set.
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Additional graphs for other basis sets and within the frozen-core approximation can be found in the {\SI}.
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Additional graphs for other basis sets and within the frozen-core approximation can be found in the {\SI}.
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\label{fig:PES-F2}
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\label{fig:PES-F2}
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}
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}
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CO_GS_VQZ.pdf
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CO_GS_VQZ.pdf
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F2_GS_VTZ.pdf
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F2_GS_VTZ.pdf
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H2_GS_VQZ.pdf
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H2_GS_VQZ.pdf
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HCl_GS_VTZ.pdf
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HCl_GS_VTZ.pdf
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LiF_GS_VQZ.pdf
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LiF_GS_VQZ.pdf
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LiH_GS_VQZ.pdf
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LiH_GS_VQZ.pdf
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N2_GS_VQZ.pdf
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N2_GS_VQZ.pdf
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