saving work

Manuscript/SRGGW.rty

@@ -116,6 +116,7 @@
 \newcommand{\hhp}{\text{2h1p}}
 \newcommand{\pph}{\text{2p1h}}
 \newcommand{\dRPA}{\text{dRPA}}
+\newcommand{\TDA}{\text{TDA}}
 \newcommand{\RPAx}{\text{RPAx}}
 \newcommand{\QP}{\textsc{quantum package}}
 \newcommand{\Hxc}{\text{Hxc}}

Manuscript/SRGGW.tex

@@ -590,22 +590,24 @@ The TDA IPs are now underestimated unlike their RPA counterparts.
 For both static self-energies, the TDA leads to a slight increase of the absolute error.
 This trend will be investigated in more details in the next subsection.
 
-Before going to the statistical study, the behavior of three particular molecules is investigated.
-The Lithium dimer \ce{Li2} will be considered as a case where HF actually underestimate the IP.
-The Lithium hydrid will also be investigated because in this case the usual qs$GW$ IP is worst than the HF one.
-Finally, the Beryllium oxyde will be studied as a prototypical example of a molecular system difficult to converge because of intruder states. \cite{vanSetten_2015,Veril_2018,Forster_2021}
+Now the flow parameter dependence of the SRG-qs$GW$ method will be investigated in three less well-behaved molecular systems.
+The left panel of Fig.~\ref{fig:fig2} shows the results for the Lithium dimer, \ce{Li2} is an interesting case because the HP IP is actually underestimated .
+On the other hand, the qs-$GW$ and SRG-qs$GW$ IPs are overestimated
+Indeed, we can see that the positive increase of the SRG-qs$GW$ IP is proportionally more important than for water.
+In addition, the plateau is reached for larger values of $s$ in comparison to Fig.~\ref{fig:fig1}.
+Both TDA results are worse than their RPA counterparts but in this case the SRG-qs$GW_\TDA$ is more accurate than the qs$GW_\TDA$.
+
+Now turning to the Lithium hydrid heterodimer, see middle panel of Fig.~\ref{fig:fig2}.
+In this case the qs$GW$ IP is actually worse than the HF one which is already pretty accurate.
+However, the SRG-qs$GW$ can improve slightly the accuracy with respect to HF.
+Finally, the Beryllium oxyde is considered as a prototypical example of a molecular system difficult to converge because of intruder states. \cite{vanSetten_2015,Veril_2018,Forster_2021}
+The SRG-qs$GW$ could be converged without any problem even for large values of $s$.
+Once again, a plateau is attained and the corresponding value is slightly more accurate than its qs$GW$ counterpart.
 
 Note that for \ce{LiH} and \ce{BeO} the TDA actually improves the accuracy compared to RPA-based qs$GW$ schemes.
 However, as we will see in the next subsection these are just particular molecular systems and in average the RPA polarizability performs better than the TDA one.
-
-% \ANT{Maybe we should add GF(2) because it allows us to explain the behavior of the SRG curve using perturbation theory.}
-% The behavior of the SRG-qsGF2 IPS is similar to the SRG-qs$GW$ one.
-% Add sentence about $GW$ better than GF2 when the results will be here.
-% The decrease and then increase behavior of the IPs can be rationalised using results from perturbation theory for GF(2).
-% We refer the reader to the chapter 8 of Ref.~\onlinecite{Schirmer_2018} for more details about this analysis.
-% The GF(2) IP admits the following perturbation expansion... \ANT{Remove GF2 and try matrix perturbation theory on $GW$, cf Evangelista's talk.}
-% Because $GW$ relies on an infinite resummation of diagram such a perturbation analysis is difficult to make in this case.
-% But the mechanism causing the increase/decrease of the $GW$ IPs as a function of $s$ should be closely related to the GF(2) one exposed above.
+Also the SRG-qs$GW_\TDA$ is better than qs$GW_\TDA$ in the three cases of Fig.~\ref{fig:fig2} but this is the other way around.
+Therefore, it seems that the effect of the TDA can not be systematically predicted.
 
 %%% FIG 2 %%% 
 \begin{figure*}