done iteration for T2

Manuscript/eDFT.tex

@@ -1255,7 +1255,7 @@ drastically.
 %If, for some reason, $W_0\approx W_1\approx W_{01}=W$, then the error
 %reduces to $-W/2$, which is weight-independent (it fits for example with
 %what you see in the weakly correlated regime). Such an assumption depends on the nature of the
-%excitation, not only on the correlation strength, right? Neverthless,
+%excitation, not only on the correlation strength, right? Nevertheless,
 %when looking at your curves, this assumption cannot be made when the
 %correlation is strong. It is not clear to me which integral ($W_{01}?$)
 %drives the all thing.\\} 
@@ -1325,7 +1325,7 @@ For small $L$, the single and double excitations can be labeled as
 ``pure'', as revealed by a thorough analysis of the FCI wavefunctions.
 In other words, each excitation is dominated by a sole, well-defined reference Slater determinant.
 However, when the box gets larger (\ie, as $L$ increases), there is a strong mixing between the different excitation degrees.
-In particular, the single and double excitations strongly mix, which makes their assignment as single or double excitations more discutable. \cite{Loos_2019}
+In particular, the single and double excitations strongly mix, which makes their assignment as single or double excitations more \titou{disputable}. \cite{Loos_2019}
 This can be clearly evidenced by the weights of the different configurations in the FCI wave function.
 % TITOU: shall we keep the paragraph below?
 %Therefore, it is paramount to construct a two-weight correlation functional
@@ -1446,8 +1446,11 @@ The influence of the correlation ensemble derivative becomes substantial in the
 \titou{For 3-boxium, in the zero-weight limit, its contribution is also significantly larger in the case of the single
 excitation; the reverse is observed in the equal-weight triensemble
 case.
-Howver, for 5- and 7-boxium, the correlation ensemble derivative hardly
-influences the double excitation (except when the correlation is strong), and slightly deteriorates the single excitation in the intermediate and strong correlation regimes}.
+However, for 5- and 7-boxium, the correlation ensemble derivative hardly
+influences the double excitation (except when the correlation is strong), and slightly deteriorates the single excitation in the intermediate and strong correlation regimes.
+This non-systematic behavior in terms of the number of electrons might be a consequence of how we constructed the weight-dependent functional.
+Indeed, as mentioned in Sec.~\ref{sec:eDFA}, the weight dependence of the eLDA functional is based on a two-electron finite uniform electron gas.
+Therefore, it might be more appropriate to model the derivative discontinuity in few-electron systems.}
 Importantly, \titou{for the single excitation}, one realizes that the magnitude of the correlation ensemble 
 derivative is \trashPFL{much} smaller in the case of equal-weight calculations (as
 compared to the zero-weight calculations).
@@ -1457,7 +1460,7 @@ compared to the zero-weight calculations).
 This could explain why equiensemble calculations are clearly more
 accurate \titou{for the single excitation} as it reduces the influence of the ensemble correlation derivative:
 for a given method, equiensemble orbitals partially remove the burden
-of modeling properly the ensemble correlation derivative.
+of modelling properly the ensemble correlation derivative.
 %\manu{Manu: I
 %do not like this statement. As I wrote above, the ensemble derivative is
 %still substantial in the strongly correlated limit of the equi