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comment on complex adiabatic connection, added figure legend

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Hugh Burton 2020-11-19 12:40:15 +00:00
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@ -499,6 +499,28 @@ and the ground-state RHF energy (Fig.~\ref{fig:HF_real})
However, in the strongly correlated regime (large $U$), the closed-shell restriction on the orbitals prevents RHF from However, in the strongly correlated regime (large $U$), the closed-shell restriction on the orbitals prevents RHF from
correctly modelling the physics of the system with the two electrons on opposing sites. correctly modelling the physics of the system with the two electrons on opposing sites.
%%% FIG 3 (?) %%%
% Analytic Continuation of HF
%%%%%%%%%%%%%%%%%
\begin{figure*}[t]
\begin{subfigure}{0.49\textwidth}
\includegraphics[height=0.65\textwidth,trim={0pt 0pt 0pt -35pt},clip]{HF_cplx_angle}
\subcaption{\label{subfig:UHF_cplx_angle}}
\end{subfigure}
\begin{subfigure}{0.49\textwidth}
\includegraphics[height=0.65\textwidth]{HF_cplx_energy}
\subcaption{\label{subfig:UHF_cplx_energy}}
\end{subfigure}
\caption{%
\hugh{(\subref{subfig:UHF_cplx_angle}) Real component of the UHF angle $\ta^{\text{UHF}}$ for $\lambda \in \bbC$.
Symmetry-broken solutions correspond to an individual sheets and become equivalent at the quasi-EP (black dot).
The RHF solution is independent of $\lambda$, giving constant plane at $\pi/2$.
(\subref{subfig:UHF_cplx_energy}) The corresponding HF energy surfaces show a non-analytic
point at the quasi-exceptional point.}
\label{fig:HF_cplx}}
\end{figure*}
%%%%%%%%%%%%%%%%%
As the on-site repulsion is increased from 0, the HF approximation reaches a critical value at $U=2t$ where a symmetry-broken As the on-site repulsion is increased from 0, the HF approximation reaches a critical value at $U=2t$ where a symmetry-broken
UHF solution appears with a lower energy than the RHF one. UHF solution appears with a lower energy than the RHF one.
This critical point is analogous to the infamous Coulson--Fischer point identified in the hydrogen dimer.\cite{Coulson_1949} This critical point is analogous to the infamous Coulson--Fischer point identified in the hydrogen dimer.\cite{Coulson_1949}
@ -523,24 +545,6 @@ of the HF energy rather than a minimum.
\subsection{Self-consistency as a perturbation} %OR {Complex adiabatic connection} \subsection{Self-consistency as a perturbation} %OR {Complex adiabatic connection}
%============================================================% %============================================================%
%%% FIG 3 (?) %%%
% Analytic Continuation of HF
%%%%%%%%%%%%%%%%%
\begin{figure*}[t]
\begin{subfigure}{0.49\textwidth}
\includegraphics[height=0.65\textwidth,trim={0pt 0pt 0pt -30pt},clip]{HF_cplx_angle}
\subcaption{\label{subfig:UHF_cplx_angle}}
\end{subfigure}
\begin{subfigure}{0.49\textwidth}
\includegraphics[height=0.65\textwidth]{HF_cplx_energy}
\subcaption{\label{subfig:UHF_cplx_energy}}
\end{subfigure}
\caption{%
Analytic continuation of HF into the complex $\lambda$ plane.
\label{fig:HF_cplx}}
\end{figure*}
%%%%%%%%%%%%%%%%%
% INTRODUCE PARAMETRISED FOCK HAMILTONIAN % INTRODUCE PARAMETRISED FOCK HAMILTONIAN
\hugh{The inherent non-linearity in the Fock eigenvalue problem arises from self-consistency \hugh{The inherent non-linearity in the Fock eigenvalue problem arises from self-consistency
in the HF approximation, and is usually solved through an iterative approach.\cite{SzaboBook} in the HF approximation, and is usually solved through an iterative approach.\cite{SzaboBook}
@ -559,6 +563,7 @@ in the Hubbard dimer directly mirror the energies shown in Fig.~\ref{fig:HF_real
with coalesence points at with coalesence points at
\begin{equation} \begin{equation}
\lambda_{\text{c}} = \pm \frac{2t}{U}. \lambda_{\text{c}} = \pm \frac{2t}{U}.
\label{eq:scaled_fock}
\end{equation} \end{equation}
In contrast, when $\lambda$ becomes complex, the HF equations become non-Hermitian and In contrast, when $\lambda$ becomes complex, the HF equations become non-Hermitian and
each HF solutions can be analytically continued for all $\lambda$ values using each HF solutions can be analytically continued for all $\lambda$ values using
@ -573,16 +578,27 @@ accurate representation for the true HF ground state at $\lambda = 1$.
For example, in the Hubbard dimer with $U > 2t$, one finds $\lambda_{\text{c}} < 1$ and the symmetry-pure orbitals For example, in the Hubbard dimer with $U > 2t$, one finds $\lambda_{\text{c}} < 1$ and the symmetry-pure orbitals
do not provide a good representation of the HF ground state. do not provide a good representation of the HF ground state.
In contrast, $U < 2t$ yields $\lambda_{\text{c}} > 1$ and corresponds to In contrast, $U < 2t$ yields $\lambda_{\text{c}} > 1$ and corresponds to
the regime where the HF ground state is correctly represented by symmetry-pure orbitals.} the regime where the HF ground state is correctly represented by symmetry-pure orbitals.
}
% COMPLEX ADIABATIC CONNECTION % COMPLEX ADIABATIC CONNECTION
\titou{In a recent paper, \cite{Burton_2019} using holomorphic Hartree-Fock (h-HF) \cite{Hiscock_2014,Burton_2018,Burton_2016} as an analytic continuation of conventional HF theory, we have demonstrated, on a simple model, that one can interconvert states of different symmetries and natures by following well-defined contours in the complex $\lambda$-plane, where $\lambda$ is the strength of the electron-electron interaction (see Fig.~\ref{fig:iAC}). \hugh{We have recently shown that the complex scaled Fock operator Eq.~\eqref{eq:scaled_fock}
In particular, by slowly varying $\lambda$ in a similar (yet different) manner to an adiabatic connection in density-functional theory, \cite{Langreth_1975,Gunnarsson_1976,Zhang_2004} one can ``morph'' a ground-state wave function into an excited-state wave function via a stationary path of HF solutions. \cite{Seidl_2018} also allows states of different symmetries to be interconverted by following a well-defined
In such a way, we could obtain a doubly-excited state wave function starting from the ground state wave function, a process which is not as easy as one might think. \cite{Gilbert_2008,Thom_2008,Shea_2018} contour in the complex $\lambda$-plane.\cite{Burton_2019}
One of the fundamental discovery we made was that Coulson-Fisher points (where multiple symmetry-broken solutions coalesce) play a central role and can be classified as \textit{quasi}-exceptional points, as the wave functions do not become self-orthogonal. In particular, by slowly varying $\lambda$ in a similar (yet different) manner
The findings reported in Ref.~\onlinecite{Burton_2019} represent the very first study of non-Hermitian quantum mechanics for the exploration of multiple solutions at the HF level. to an adiabatic connection in density-functional theory,\cite{Langreth_1975,Gunnarsson_1976,Zhang_2004}
It perfectly illustrates the deeper topology of electronic states revealed using a complex-scaled electron-electron interaction. a ground-state wave function can be ``morphed'' into an excited-state wave function
Through the introduction of non-Hermiticity, we have provided a more general framework in which the complex and diverse characteristics of multiple solutions can be explored and understood.} via a stationary path of HF solutions.
This novel approach to identifying excited-state wave functions demonstrates the fundamental
role of quasi-EPs in determining the behaviour of the HF approximation.}
%\titou{In a recent paper, \cite{Burton_2019} using holomorphic Hartree-Fock (h-HF) \cite{Hiscock_2014,Burton_2018,Burton_2016} as an analytic continuation of conventional HF theory, we have demonstrated, on a simple model, that one can interconvert states of different symmetries and natures by following well-defined contours in the complex $\lambda$-plane, where $\lambda$ is the strength of the electron-electron interaction (see Fig.~\ref{fig:iAC}).
%In particular, by slowly varying $\lambda$ in a similar (yet different) manner to an adiabatic connection in density-functional theory, \cite{Langreth_1975,Gunnarsson_1976,Zhang_2004} one can ``morph'' a ground-state wave function into an excited-state wave function via a stationary path of HF solutions. \cite{Seidl_2018}
%In such a way, we could obtain a doubly-excited state wave function starting from the ground state wave function, a process which is not as easy as one might think. \cite{Gilbert_2008,Thom_2008,Shea_2018}
%One of the fundamental discovery we made was that Coulson-Fisher points (where multiple symmetry-broken solutions coalesce) play a central role and can be classified as \textit{quasi}-exceptional points, as the wave functions do not become self-orthogonal.
%The findings reported in Ref.~\onlinecite{Burton_2019} represent the very first study of non-Hermitian quantum mechanics for the exploration of multiple solutions at the HF level.
%It perfectly illustrates the deeper topology of electronic states revealed using a complex-scaled electron-electron interaction.
%Through the introduction of non-Hermiticity, we have provided a more general framework in which the complex and diverse characteristics of multiple solutions can be explored and understood.}
%=====================================================% %=====================================================%
\subsection{M{\o}ller-Plesset perturbation theory} \subsection{M{\o}ller-Plesset perturbation theory}