update MP

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Pierre-Francois Loos 2020-11-19 09:35:39 +01:00
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commit 152f276eb1
5 changed files with 44 additions and 21 deletions

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%Control: page (0) single %Control: page (0) single
%Control: year (1) truncated %Control: year (1) truncated
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\begin{thebibliography}{93}% \begin{thebibliography}{94}%
\makeatletter \makeatletter
\providecommand \@ifxundefined [1]{% \providecommand \@ifxundefined [1]{%
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@ -504,6 +504,15 @@
{Ostlund}},\ }\href@noop {} {\emph {\bibinfo {title} {Modern quantum {Ostlund}},\ }\href@noop {} {\emph {\bibinfo {title} {Modern quantum
chemistry: {Introduction} to advanced electronic structure}}}\ (\bibinfo chemistry: {Introduction} to advanced electronic structure}}}\ (\bibinfo
{publisher} {McGraw-Hill},\ \bibinfo {year} {1989})\BibitemShut {NoStop}% {publisher} {McGraw-Hill},\ \bibinfo {year} {1989})\BibitemShut {NoStop}%
\bibitem [{\citenamefont {Mayer}\ and\ \citenamefont
{L{\"o}wdin}(1993)}]{Mayer_1993}%
\BibitemOpen
\bibfield {author} {\bibinfo {author} {\bibfnamefont {I.}~\bibnamefont
{Mayer}}\ and\ \bibinfo {author} {\bibfnamefont {P.-O.}\ \bibnamefont
{L{\"o}wdin}},\ }\href {\doibase
https://doi.org/10.1016/0009-2614(93)85341-K} {\bibfield {journal} {\bibinfo
{journal} {Chemical Physics Letters}\ }\textbf {\bibinfo {volume} {202}},\
\bibinfo {pages} {1 } (\bibinfo {year} {1993})}\BibitemShut {NoStop}%
\bibitem [{\citenamefont {Coulson}\ and\ \citenamefont \bibitem [{\citenamefont {Coulson}\ and\ \citenamefont
{Fischer}()}]{Coulson_1949}% {Fischer}()}]{Coulson_1949}%
\BibitemOpen \BibitemOpen

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%% This BibTeX bibliography file was created using BibDesk. %% This BibTeX bibliography file was created using BibDesk.
%% http://bibdesk.sourceforge.net/ %% http://bibdesk.sourceforge.net/
%% Created for Pierre-Francois Loos at 2020-11-18 21:23:03 +0100 %% Created for Pierre-Francois Loos at 2020-11-19 09:09:27 +0100
%% Saved with string encoding Unicode (UTF-8) %% Saved with string encoding Unicode (UTF-8)
@article{Mayer_1993,
abstract = {A study is made of the general Hartree---Fock (GHF) method, in which the basic spin-orbitals may be mixtures of functions having α and β spins. The existence of the solutions to the GHF equations has been proven by Lieb and Simon, and the nature of the various types of solutions has been group theoretically classified by Fukutome. Some numerical applications using Gaussian bases are carried out for some simple systems: the beryllium and carbon atoms and the BH molecule. Some GHF solutions of the general Fukutome-type ``torsional spin density waves'' (TSDW) were found.},
author = {Istv{\'a}n Mayer and Per-Olov L{\"o}wdin},
date-added = {2020-11-19 09:09:18 +0100},
date-modified = {2020-11-19 09:09:26 +0100},
doi = {https://doi.org/10.1016/0009-2614(93)85341-K},
issn = {0009-2614},
journal = {Chemical Physics Letters},
number = {1},
pages = {1 - 6},
title = {Some comments on the general Hartree---Fock method},
url = {http://www.sciencedirect.com/science/article/pii/000926149385341K},
volume = {202},
year = {1993},
Bdsk-Url-1 = {http://www.sciencedirect.com/science/article/pii/000926149385341K},
Bdsk-Url-2 = {https://doi.org/10.1016/0009-2614(93)85341-K}}
@article{Zhang_2004, @article{Zhang_2004,
author = {Zhang, Fan and Burke, Kieron}, author = {Zhang, Fan and Burke, Kieron},
date-added = {2020-11-18 21:23:02 +0100}, date-added = {2020-11-18 21:23:02 +0100},

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@ -445,7 +445,7 @@ from the one-electron Fock operators as
From hereon, $i$ and $j$ denote occupied orbitals, $a$ and $b$ denote unoccupied (or virtual) orbitals, while $p$, $q$, $r$, and $s$ denote arbitrary orbitals. From hereon, $i$ and $j$ denote occupied orbitals, $a$ and $b$ denote unoccupied (or virtual) orbitals, while $p$, $q$, $r$, and $s$ denote arbitrary orbitals.
% BRIEF FLAVOURS OF HF % BRIEF FLAVOURS OF HF
In the most flexible variant of real HF theory (generalised HF) the one-electron orbitals can be complex-valued In the most flexible variant of real HF theory (generalised HF \cite{Mayer_1993}) the one-electron orbitals can be complex-valued
and contain a mixture of spin-up and spin-down components.\cite{Mayer_1993} and contain a mixture of spin-up and spin-down components.\cite{Mayer_1993}
However, the application of HF with some level of constraint on the orbital structure is far more common. However, the application of HF with some level of constraint on the orbital structure is far more common.
Forcing the spatial part of the orbitals to be the same for spin-up and spin-down electrons leads to restricted HF (RHF) theory, while allowing different for different spins leads to the so-called unrestricted HF (UHF) approach. Forcing the spatial part of the orbitals to be the same for spin-up and spin-down electrons leads to restricted HF (RHF) theory, while allowing different for different spins leads to the so-called unrestricted HF (UHF) approach.
@ -634,7 +634,7 @@ Interestingly, one can show that the convergent and divergent series start to di
\end{subfigure} \end{subfigure}
\caption{ \caption{
Convergence of the RMP series as a function of the perturbation order $n$ for the Hubbard dimer at $U/t = 3.5$ (where $r_c > 1$) and $4.5$ (where $r_c < 1$). Convergence of the RMP series as a function of the perturbation order $n$ for the Hubbard dimer at $U/t = 3.5$ (where $r_c > 1$) and $4.5$ (where $r_c < 1$).
The Riemann surfaces associated with the exact energy of the RMP Hamiltonian \eqref{eq:H_RMP} are also represented for these two values of $U/t$. The Riemann surfaces associated with the exact energies of the RMP Hamiltonian \eqref{eq:H_RMP} are also represented for these two values of $U/t$ as functions of $\lambda$.
\label{fig:RMP}} \label{fig:RMP}}
\end{figure*} \end{figure*}
@ -652,30 +652,27 @@ The UMP partitioning yield the following $\lambda$-dependent Hamiltonian:
\end{pmatrix}, \end{pmatrix},
\end{equation} \end{equation}
\end{widetext} \end{widetext}
A closed-form expression for the ground-state energy can be obtained but it is cumbersome, so we eschew reporting its expression. A closed-form expression for the ground-state energy can be obtained but it is cumbersome, so we eschew reporting it.
The radius of convergence of the UMP series can obtained numerically as a function of $U/t$ and is depicted in Fig.~\ref{eq:UMP_rc}. The radius of convergence of the UMP series can obtained numerically as a function of $U/t$ and is depicted in \titou{Fig.~\ref{eq:UMP_rc}}.
The convergence of the UMP as a function of the ratio $U/t$ is shown in Fig.~\ref{subfig:UMP_cvg} for two specific values: the first ($U = 3t$) is well within the RMP convergence region, while the second ($U = 7t$) falls outside.
Note that in the case of UMP, there are now two pairs of EPs as the open-shell singlet now couples strongly with both the ground and doubly-excited states. Note that in the case of UMP, there are now two pairs of EPs as the open-shell singlet now couples strongly with both the ground and doubly-excited states.
This has the clear tendency to move away from the origin the EP dictating the convergence of the ground-state energy, while deteriorating the convergence properties of the excited-state energy. This has the clear tendency to move away from the origin the EP dictating the convergence of the ground-state energy, while deteriorating the convergence properties of the excited-state energy.
For $U = 3t$ (see Fig.~\ref{subfig:UMP_3}), the ground-state energy is remarkably flat since the UHF energy is already a pretty good estimate of the exact energy thanks to the symmetry-breaking process.
The convergence of the UMP as a function of the ratio $U/t$ is shown in Fig.~\ref{fig:UMP} for two specific values: the first ($U = 3t$) is well within the RMP convergence region, while the second ($U = 7t$) falls outside.
For $U = 3t$ (see Fig.~\ref{subfig:UMP_3}), the ground-state energy is remarkably flat since the UHF energy is a pretty good estimate.
Most of the UMP expansion is actually correcting the spin-contamination in the wave function. Most of the UMP expansion is actually correcting the spin-contamination in the wave function.
For $U = 7t$ (see Fig.~\ref{subfig:UMP_7}), we are well towards the strong correlation regime, where we see that the UMP series is slowly convergent while RMP diverges. For $U = 7t$ (see Fig.~\ref{subfig:UMP_7}), we are well towards the strong correlation regime, where we see that the UMP series is slowly convergent while RMP diverges.
We see a single EP on the ground-state surface which falls just outside (maybe on?) the radius of convergence. We see a single EP on the ground-state surface which falls just outside (maybe on?) the radius of convergence.
An EP this close to the radius of convergence gives an increasingly slow convergence of the UMP series, but it will converge eventually! An EP this close to the radius of convergence gives an increasingly slow convergence of the UMP series, but it will converge eventually as observed in Fig.~\ref{subfig:UMP_cvg}.
%On the other hand, there is an EP on the excited energy surface that is well within the radius of convergence.
On the other hand, there is an exceptional point on the excited energy surface that is well within the radius of convergence. %We can therefore say that the use of a symmetry-broken UHF wave function can retain a convergent ground-state perturbation series
We can therefore say that the use of a symmetry-broken UHF wave function can retain a convergent ground-state perturbation series %at the expense of a divergent excited-state perturbation series. (Note: the orbitals are not optimised for excited-state here).
at the expense of a divergent excited-state perturbation series. (Note: the orbitals are not optimised for excited-state here). %In contrast, the RMP expansion was always convergent for the open-shell excited state (which was a single CSF) while
In contrast, the RMP expansion was always convergent for the open-shell excited state (which was a single CSF) while %the radius of convergence for the doubly-excited state was identical to the ground-state as this was the only exceptional point.
the radius of convergence for the doubly-excited state was identical to the ground-state as this was the only exceptional point.
%%% FIG 3 %%% %%% FIG 3 %%%
\begin{figure*} \begin{figure*}
\begin{subfigure}{0.32\textwidth} \begin{subfigure}{0.32\textwidth}
\includegraphics[height=0.75\textwidth]{fig3c} \includegraphics[height=0.75\textwidth]{fig3a}
\subcaption{\label{subfig:UMP_3} $U/t = 3$} \subcaption{\label{subfig:UMP_3} $U/t = 3$}
\end{subfigure} \end{subfigure}
% %
@ -685,11 +682,11 @@ the radius of convergence for the doubly-excited state was identical to the grou
\end{subfigure} \end{subfigure}
% %
\begin{subfigure}{0.32\textwidth} \begin{subfigure}{0.32\textwidth}
\includegraphics[height=0.75\textwidth]{fig3a} \includegraphics[height=0.75\textwidth]{fig3c}
\subcaption{\label{subfig:UMP_7} $U/t = 7$} \subcaption{\label{subfig:UMP_7} $U/t = 7$}
\end{subfigure} \caption{ \end{subfigure} \caption{
Convergence of the UMP series as a function of the perturbation order $n$ for the Hubbard dimer at $U/t = 3$ and $7$. Convergence of the UMP series as a function of the perturbation order $n$ for the Hubbard dimer at $U/t = 3$ and $7$.
The Riemann surfaces of the FCI energies are also represented for these two values of $U/t$. The Riemann surfaces associated with the exact energies of the UMP Hamiltonian \eqref{eq:H_UMP} are also represented for these two values of $U/t$ as functions of $\lambda$.
\label{fig:UMP}} \label{fig:UMP}}
\end{figure*} \end{figure*}

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