modifs in manuscript

Manuscript/SRGGW.tex

@@ -207,7 +207,7 @@ with
 \end{subequations}
 and where
 \begin{equation}
-	\braket{pq}{rs} = \iint \frac{\textcolor{red}{\SO{p}^*(\bx_1) \SO{q}^*(\bx_2)}\SO{r}(\bx_1) \SO{s}(\bx_2)  }{\abs{\br_1 - \br_2}} d\bx_1 d\bx_2
+	\braket{pq}{rs} = \iint \frac{\SO{p}(\bx_1) \SO{q}(\bx_2)\SO{r}(\bx_1) \SO{s}(\bx_2)  }{\abs{\br_1 - \br_2}} d\bx_1 d\bx_2
 \end{equation}
 are bare two-electron integrals in the spin-orbital basis.
 
@@ -633,11 +633,13 @@ Performing a bijective transformation of the form,
   e^{- \Delta s} &= 1-e^{-\Delta t},
 \end{align}
 on the renormalized quasiparticle equation \eqref{eq:GW_renorm} reverses the situation and makes it possible to choose $t$ such that there is no intruder states in the dynamic part, hence removing discontinuities.
-
-\textcolor{red}{The intruder-state free dynamic part makes it possible to define a SRG-$G_0W_0$ and SRG-ev$GW$.
-The main manuscript focus on SRG-qs$GW$ but the performance of SRG-$G_0W_0$ and SRG-ev$GW$ are discussed in the {\SupInf} for the sake of completeness.}
 Note that, after this transformation, the form of the regularizer is actually closely related to the SRG-inspired regularizer introduced by Monino and Loos in Ref.~\onlinecite{Monino_2022}.
 
+\textcolor{red}{The intruder-state-free dynamic part of the self-energy makes it possible to define SRG-$G_0W_0$ and SRG-ev$GW$ schemes.
+Although the manuscript focuses on SRG-qs$GW$, the performance of SRG-$G_0W_0$ and SRG-ev$GW$ are discussed in the {\SupInf} for the sake of completeness.
+In a nutshell, the SRG regularization improves the overall convergence properties of SRG-ev$GW$ without altering its performance.
+Likewise, the statistical indicators for $G_0W_0$ and SRG-$G_0W_0$ are extremely close.}
+
 %=================================================================%
 \section{Computational details}
 \label{sec:comp_det}