DNA + abstract

Data/DNA.dat

@@ -0,0 +1,5 @@
+A 73-24-5 -7.265806 -1.211220672617561E-002 -1.385783048793831E-002 -7.748 -7.975 -8.15  -8.33 -8.48
+C 71-30-7 -7.527844 -1.546006861838614E-002 -1.940117174135618E-002 -8.067 -8.287 -8.449 -9.512 -8.94
+G 73-40-5 -6.951933 -1.225096955803263E-002 -1.413179166956595E-002 -7.461 -7.691 -7.872 -8.034 -8.24
+T 65-71-4 -8.019884 -1.231951892771176E-002 -1.437665931379063E-002 -8.489 -8.708 -8.866 -9.081 -9.2
+U 66-22-8 -8.379481 -1.561024372083486E-002 -1.963262364674972E-002 -9.017 -9.223 -9.382 -10.125 -9.68

Data/DNA_G0W0PBE0_def2SVP.dat

@@ -1,5 +0,0 @@
-A 73-24-5 -7.619669	-1.188807989121034E-002 -1.347846624909449E-002 -7.748 -7.975 -8.15
-T 65-71-4 -8.430762 	-1.213173859277770E-002 -1.403130444037225E-002 -8.489 -8.708 -8.866
-G 73-40-5 -7.314073     -1.205464000600519E-002 -1.378918997228398E-002 -7.461 -7.691 -7.872 
-C 71-30-7 -7.971438     -1.309683725056005E-002 -1.554126377782151E-002 -8.067 -8.287 -8.449 
-U 66-22-8 -8.814516     -1.240474844370148E-002 -1.441015016892908E-002 -9.017 -9.223 -9.382

Manuscript/GW-srDFT.tex

@@ -15,6 +15,8 @@
     urlcolor=blue,
     citecolor=blue
 }
+\urlstyle{same}
+
 \newcommand{\alert}[1]{\textcolor{red}{#1}}
 \definecolor{darkgreen}{HTML}{009900}
 \usepackage[normalem]{ulem}
@@ -176,6 +178,8 @@
 %	\centering
 %  \includegraphics[width=\linewidth]{TOC}
 %\end{wrapfigure}
+Similarly to other electron correlation methods, many-body perturbation theory methods, such as the so-called GW approximation, suffer from the usual slow convergence of energetic properties with respect to the size of the one-electron basis functions due to the lack of explicit electron-electron terms modeling the infamous electron-electron cusp.
+Here, we propose a density-based basis set correction which significantly speed up the convergence of energetics towards the complete basis set limit.
 \end{abstract}
 
 \maketitle
@@ -362,30 +366,31 @@ Unless otherwise stated, in the remaining of this paper, the {\GOWO} QP energies
 In the case of {\evGW}, the QP energy, $\eGW{p}$, are obtained via Eq.~\eqref{eq:QP-G0W0}, which has to be solved self-consistently due to the QP energy dependence of the self-energy [see Eq.~\eqref{eq:SigC}]. \cite{Hybertsen_1986, Shishkin_2007, Blase_2011, Faber_2011} 
 At least in the weakly correlated regime where a clear QP solution exists, we believe that, within {\evGW}, the self-consistent algorithm should select the solution of the QP equation \eqref{eq:QP-G0W0} with the largest renormalization weight $\Z{p}(\eGW{p})$.
 
-%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
-\subsection{Basis Set Correction}
-%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
-The present basis set correction is a two-level correction.
-First, one has to correct the neutral excitations $\Om{x}$ from the RPA calculation.
-The corrected matrix elements read 
-\begin{align}
-\label{eq:RPA}
-	\tA_{ia,jb} & = \A{ia,jb} + (ia|\fc|jb),
-	&
-	\tB_{ia,jb} & = \B{ia,jb} + (ia|\fc|bj),
-\end{align}
-where the elements $\A{ia,jb}$ and $\B{ia,jb}$ are given by Eq.~\eqref{eq:RPA}.
-\begin{equation}
-	\fc(\br{1},\br{2})= \frac{\delta^2 \Ec}{\delta n(\br{1})\delta n(\br{2})}
-\end{equation}
-In a second time, we correct the GW energy
-\begin{equation}
-	\tSigC{p} = \SigC{p} + (p|\Vc|p)
-\end{equation}
-with
-\begin{equation}
-	\Vc(\br{}) = \fdv{\Ec}{n(\br{})}
-\end{equation}
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%\subsection{Basis Set Correction}
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%The present basis set correction is a two-level correction.
+%First, one has to correct the neutral excitations $\Om{x}$ from the RPA calculation.
+%The corrected matrix elements read 
+%\begin{align}
+%\label{eq:RPA}
+%	\tA_{ia,jb} & = \A{ia,jb} + (ia|\fc|jb),
+%	&
+%	\tB_{ia,jb} & = \B{ia,jb} + (ia|\fc|bj),
+%\end{align}
+%where the elements $\A{ia,jb}$ and $\B{ia,jb}$ are given by Eq.~\eqref{eq:RPA}.
+%\begin{equation}
+%	\fc(\br{1},\br{2})= \frac{\delta^2 \Ec}{\delta n(\br{1})\delta n(\br{2})}
+%\end{equation}
+%In a second time, we correct the GW energy
+%\begin{equation}
+%	\tSigC{p} = \SigC{p} + (p|\Vc|p)
+%\end{equation}
+%with
+%\begin{equation}
+%	\Vc(\br{}) = \fdv{\Ec}{n(\br{})}
+%\end{equation}
+
 %%%%%%%%%%%%%%%%%%%%%%%%
 \section{Computational details}
 \label{sec:compdetails}
@@ -396,6 +401,37 @@ with
 \label{sec:res}
 %%%%%%%%%%%%%%%%%%%%%%%%
 
+%%% TABLE I %%%
+\begin{table*}
+\caption{
+IPs (in eV) of the five canonical nucleobases computed at various levels of theory.
+\label{tab:DNA}
+}
+	\begin{ruledtabular}
+		\begin{tabular}{llddddd}
+									&				&	\mc{5}{c}{IPs of nucleobases (eV)}					\\	
+														\cline{3-7}										
+		Method						&	Basis		&	\tabc{Adenine} 	&	\tabc{Cytosine}	&	\tabc{Thymine}		&	\tabc{Guanine}	& \tabc{Uracil}	\\	
+		\hline
+		{\GOWO}@PBE\fnm[1]			&	def2-SVP	&	7.27	&	7.53	&	6.95	&	8.02	&	8.38	\\
+		{\GOWO}@PBE+srLDA\fnm[1]	&	def2-SVP	&	7.60	&	7.95	&	7.29	&	8.36	&	8.80	\\
+		{\GOWO}@PBE+srPBE\fnm[1]	&	def2-SVP	&	7.64	&	8.06	&	7.34	&	8.41	&	8.91	\\
+		{\GOWO}@PBE\fnm[2]			&	def2-TZVP	&	7.75	&	8.07	&	7.46	&	8.49	&	9.02	\\
+		{\GOWO}@PBE+srLDA\fnm[1]	&	def2-TZVP	&		&		&		&		&		\\
+		{\GOWO}@PBE+srPBE\fnm[1]	&	def2-TZVP	&		&		&		&		&		\\
+		{\GOWO}@PBE\fnm[2]			&	def2-QZVP	&	7.98	&	8.29	&	7.69	&	8.71	&	9.22	\\
+		{\GOWO}@PBE\fnm[3]			&	def2-TQZVP	&	8.15	&	8.45	&	7.87	&	8.87	&	9.38	\\
+		\hline
+		CCSD(T)\fnm[4]				&	def2-TZVPP	&	8.33	&	9.51	&	8.03	&	9.08	&	10.13	\\
+		Experiment\fnm[5]			&				&	8.48	&	8.94	&	8.24	&	9.2		&	9.68	\\
+		\end{tabular}
+	\end{ruledtabular}
+	\fnt[1]{This work.}
+	\fnt[2]{Unpublished data taken from \url{https://gw100.wordpress.com}.}
+	\fnt[3]{Extrapolated values obtained from the def2-TZVP and def2-QZVP values.}
+	\fnt[4]{Reference \onlinecite{Krause_2015}.}
+	\fnt[5]{Experimental values taken from Ref.~\onlinecite{Maggio_2017}.}
+\end{table*}
 
 
 %%%%%%%%%%%%%%%%%%%%%%%%
@@ -409,7 +445,10 @@ with
 
 %%%%%%%%%%%%%%%%%%%%%%%%
 \begin{acknowledgements}
-This work was performed using HPC resources from GENCI-TGCC (Grant No.~2018-A0040801738), CALMIP (Toulouse) under allocation 2019-18005 and the Jarvis-Alpha cluster from the \textit{Institut Parisien de Chimie Physique et Th\'eorique}.
+PFL would like to thank Fabien Bruneval for technical assistance. He also would like to thank Arjan Berger and Pina Romaniello for stimulating discussions.
+This work was performed using HPC resources from GENCI-TGCC (Grant No.~2018-A0040801738) and CALMIP (Toulouse) under allocation 2019-18005.
+Funding from the \textit{``Centre National de la Recherche Scientifique''} is acknowledged.
+This work has been supported through the EUR grant NanoX ANR-17-EURE-0009 in the framework of the \textit{``Programme des Investissements d'Avenir''}.
 \end{acknowledgements}
 %%%%%%%%%%%%%%%%%%%%%%%%