saving work in results

Manuscript/SRGGW.tex

@@ -647,7 +647,7 @@ However, in order to perform a black-box comparison, these parameters have been
 
 The results section is divided into two parts.
 The first step will be to analyze in depth the behavior of the two static self-energy approximations in a few test cases.
-Then the accuracy of the IP yielded by the traditional and SRG schemes will be statistically gauged over a test set of molecules.
+Then, the accuracy of the principal IPs and EAs produced by the qs$GW$ and SRG-qs$GW$ schemes are statistically gauged over the test set of molecules described in Sec.~\ref{sec:comp_det}.
 
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 \subsection{Flow parameter dependence of the SRG-qs$GW$ scheme}
@@ -675,18 +675,19 @@ Then the accuracy of the IP yielded by the traditional and SRG schemes will be s
 \end{figure*}
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-This section starts by considering a prototypical molecular system, \ie the water molecule, in the aug-cc-pVTZ cartesian basis set.
+This section starts by considering a prototypical molecular system, \ie the water molecule, in the aug-cc-pVTZ basis set.
 Figure \ref{fig:fig2} shows the error of various methods for the principal IP with respect to the CCSD(T) reference value.
-The HF IP (dashed black line) is overestimated; this is a consequence of the missing correlation and the lack of orbital relaxation for the cation, a result that is well understood. \cite{SzaboBook,Lewis_2019}
-The usual qs$GW$ scheme (dashed blue line) brings a quantitative improvement as the IP is now within \SI{0.3}{\electronvolt} of the reference.
+The IP at the HF level (dashed black line) is overestimated; this is a consequence of the missing correlation and the lack of orbital relaxation for the cation, a result that is well understood. \cite{SzaboBook,Lewis_2019}
+The usual qs$GW$ scheme (dashed blue line) brings a quantitative improvement as the IP is now within \SI{0.3}{\eV} of the reference.
 
-Figure~\ref{fig:fig2} also displays the SRG-qs$GW$ IP as a function of the flow parameter (blue curve).
-At $s=0$, the IP is equal to its HF counterpart as expected from the discussion of Sec.~\ref{sec:srggw}.
-For $s\to\infty$, the IP reaches a plateau at an error that is significantly smaller than their $s=0$ starting point.
-Even more, the value associated with this plateau is slightly more accurate than its qs$GW$ counterpart.
-However, the SRG-qs$GW$ error do not decrease smoothly between the initial HF value and the $s\to\infty$ limit as for small $s$ values it is actually worst than the HF starting point.
+Figure \ref{fig:fig2} also displays the IP at the SRG-qs$GW$ level as a function of the flow parameter (blue curve).
+At $s=0$, the SRG-qs$GW$ IP is equal to its HF counterpart as expected from the discussion of Sec.~\ref{sec:srggw}.
+As $s\to\infty$, the IP reaches a plateau at an error that is significantly smaller than their $s=0$ starting point.
+Furthermore, the value associated with this plateau is slightly more accurate than its qs$GW$ counterpart.
+However, the SRG-qs$GW$ error does not decrease smoothly between the initial HF value and the $s\to\infty$ limit. 
+For small $s$, it is actually worse than the HF starting point.
 
-This behavior as a function of $s$ can be approximately rationalized by applying matrix perturbation theory on Eq.~(\ref{eq:GWlin}).
+This behavior as a function of $s$ can be understood by applying matrix perturbation theory on Eq.~\eqref{eq:GWlin}.
 Through second order in the coupling block, the principal IP is
 \begin{equation}
   \label{eq:2nd_order_IP}