\documentclass[aps,prb,reprint,noshowkeys,superscriptaddress]{revtex4-1} \usepackage{subcaption} \usepackage{bm,graphicx,tabularx,array,booktabs,dcolumn,xcolor,microtype,multirow,amscd,amsmath,amssymb,amsfonts,physics,siunitx,mhchem} \usepackage[utf8]{inputenc} \usepackage[T1]{fontenc} \usepackage{txfonts} \usepackage[normalem]{ulem} \definecolor{hughgreen}{RGB}{0, 128, 0} \newcommand{\titou}[1]{\textcolor{red}{#1}} \newcommand{\hugh}[1]{\textcolor{hughgreen}{#1}} \newcommand{\hughDraft}[1]{\textcolor{orange}{#1}} \newcommand{\trash}[1]{\textcolor{red}{\sout{#1}}} \newcommand{\trashHB}[1]{\textcolor{orange}{\sout{#1}}} \newcommand{\antoine}[1]{\textcolor{cyan}{#1}} \usepackage[ colorlinks=true, citecolor=blue, linkcolor=blue, filecolor=blue, urlcolor=blue, breaklinks=true ]{hyperref} \urlstyle{same} \newcommand{\ctab}{\multicolumn{1}{c}{---}} \newcommand{\latin}[1]{#1} %\newcommand{\latin}[1]{\textit{#1}} \newcommand{\ie}{\latin{i.e.}} \newcommand{\eg}{\latin{e.g.}} \newcommand{\etal}{\textit{et al.}} \newcommand{\mc}{\multicolumn} \newcommand{\fnm}{\footnotemark} \newcommand{\fnt}{\footnotetext} \newcommand{\mcc}[1]{\multicolumn{1}{c}{#1}} \newcommand{\mr}{\multirow} % operators \newcommand{\bH}{\mathbf{H}} \newcommand{\bV}{\mathbf{V}} \newcommand{\bh}{\mathbf{h}} \newcommand{\bQ}{\mathbf{Q}} \newcommand{\bSig}{\mathbf{\Sigma}} \newcommand{\br}{\mathbf{r}} \newcommand{\bp}{\mathbf{p}} \newcommand{\cP}{\mathcal{P}} \newcommand{\cS}{\mathcal{S}} \newcommand{\cT}{\mathcal{T}} \newcommand{\cC}{\mathcal{C}} \newcommand{\PT}{\mathcal{PT}} \newcommand{\EPT}{E_{\PT}} \newcommand{\laPT}{\lambda_{\PT}} \newcommand{\EEP}{E_\text{EP}} \newcommand{\laEP}{\lambda_\text{EP}} \newcommand{\Ne}{N} % Number of electrons \newcommand{\Nn}{M} % Number of nuclei \newcommand{\hI}{\Hat{I}} \newcommand{\hH}{\Hat{H}} \newcommand{\hS}{\Hat{S}} \newcommand{\hT}{\Hat{T}} \newcommand{\hW}{\Hat{W}} \newcommand{\hV}{\Hat{V}} \newcommand{\hc}[2]{\Hat{c}_{#1}^{#2}} \newcommand{\hn}[1]{\Hat{n}_{#1}} \newcommand{\n}[1]{n_{#1}} \newcommand{\Dv}{\Delta v} \newcommand{\ra}{\rightarrow} \newcommand{\up}{\uparrow} \newcommand{\dw}{\downarrow} \newcommand{\updot}{% \mathrel{\ooalign{\hfil$\vcenter{ \hbox{$\scriptscriptstyle\bullet$}}$\hfil\cr$\uparrow$\cr} }% } \newcommand{\dwdot}{% \mathrel{\ooalign{\hfil$\vcenter{ \hbox{$\scriptscriptstyle\bullet$}}$\hfil\cr$\downarrow$\cr} }% } \newcommand{\vac}{% \mathrel{\ooalign{\hfil$\vcenter{ \hbox{$\scriptscriptstyle\bullet$}}$\hfil\cr$ $\cr} }% } \newcommand{\uddot}{% \mathrel{\ooalign{\hfil$\vcenter{ \hbox{$\scriptscriptstyle\bullet$}}$\hfil\cr$\uparrow\downarrow$\cr} }% } % Center tabularx columns \newcolumntype{Y}{>{\centering\arraybackslash}X} % HF rotation angles \newcommand{\ta}{\theta_{\alpha}} \newcommand{\tb}{\theta_{\beta}} % Some constants \renewcommand{\i}{\mathrm{i}} % Imaginary unit \newcommand{\e}{\mathrm{e}} % Euler number \newcommand{\rc}{r_{\text{c}}} \newcommand{\lc}{\lambda_{\text{c}}} \newcommand{\lp}{\lambda_{\text{p}}} \newcommand{\lep}{\lambda_{\text{EP}}} % Some energies \newcommand{\Emp}{E_{\text{MP}}} % Blackboard bold \newcommand{\bbR}{\mathbb{R}} \newcommand{\bbC}{\mathbb{C}} % Making life easier \newcommand{\Lup}{\mathcal{L}^{\uparrow}} \newcommand{\Ldown}{\mathcal{L}^{\downarrow}} \newcommand{\Lsi}{\mathcal{L}^{\sigma}} \newcommand{\Rup}{\mathcal{R}^{\uparrow}} \newcommand{\Rdown}{\mathcal{R}^{\downarrow}} \newcommand{\Rsi}{\mathcal{R}^{\sigma}} \newcommand{\vhf}{v_{\text{HF}}} \newcommand{\LCPQ}{Laboratoire de Chimie et Physique Quantiques (UMR 5626), Universit\'e de Toulouse, CNRS, UPS, France.} \newcommand{\UCAM}{Department of Chemistry, University of Cambridge, Lensfield Road, Cambridge, CB2 1EW, U.K.} \newcommand{\UOX}{Physical and Theoretical Chemical Laboratory, Department of Chemistry, University of Oxford, Oxford, OX1 3QZ, U.K.} \begin{document} \title{Perturbation Theory in the Complex Plane: Exceptional Points and Where to Find Them} \author{Antoine \surname{Marie}} \affiliation{\LCPQ} \author{Hugh G.~A.~\surname{Burton}} \email{hugh.burton@chem.ox.ac.uk} \affiliation{\UOX} \author{Pierre-Fran\c{c}ois \surname{Loos}} \email{loos@irsamc.ups-tlse.fr} \affiliation{\LCPQ} \begin{abstract} We explore the extension of quantum chemistry in the complex plane and its link with perturbation theory. We observe that the physics of a quantum system is intimately connected to the position of energy singularities in the complex plane, known as exceptional points. After a presentation of the fundamental notions of quantum chemistry in the complex plane, such as the mean-field Hartree--Fock approximation and Rayleigh-Schr\"odinger perturbation theory, we provide a historical overview of the various research activities that have been performed on the physics of singularities. In particular, we highlight the seminal work of several research groups on the convergence behaviour of perturbative series obtained within M{\o}ller--Plesset perturbation theory and its apparent link with quantum phase transitions. We also discuss several resummation techniques (such as Pad\'e and quadratic approximants) able to improve the overall accuracy of the M{\o}ller--Plesset perturbative series in both convergent and divergent cases. Each of these points is further illustrated with the ubiquitous Hubbard dimer at half filling which proves to be a versatile model system in order to understand the subtle concepts of the analytic continuation of perturbation theory into the complex plane. \end{abstract} \maketitle %\raggedbottom %\tableofcontents %%%%%%%%%%%%%%%%%%%%%%% \section{Introduction} \label{sec:intro} %%%%%%%%%%%%%%%%%%%%%%% % Good old Schroedinger The electronic Schr\"odinger equation, \begin{equation} \hH \Psi = E \Psi, \end{equation} is the starting point for a fundamental understanding of the behaviour of electrons and, thence, of chemical structure, bonding and reactivity. However, as famously stated by Dirac: \cite{Dirac_1929} \begin{quote} \textit{``The underlying physical laws necessary for the mathematical theory of a large part of physics and the whole of chemistry are thus completely known, and the difficulty is only that the exact application of these laws leads to equations much too complicated to be soluble. It therefore becomes desirable that approximate practical methods of applying quantum mechanics should be developed, which can lead to an explanation of the main features of complex atomic systems without too much computation.''} \end{quote} Indeed, as anticipated by Dirac, accurately predicting the energetics of electronic states from first principles has been one of the grand challenges faced by theoretical chemists and physicists since the dawn of quantum mechanics. % RSPT Together with the variational principle, perturbation theory is one of the very few essential tool for describing realistic quantum systems for which it is impossible to find the exact solution of the Schr\"odinger equation. In particular, time-independent Rayleigh--Schr\"odinger perturbation theory \cite{RayleighBook,Schrodinger_1926} has cemented itself as an instrument of choice in the armada of theoretical and computational methods that have been developed for this purpose. \cite{SzaboBook,JensenBook,CramerBook,HelgakerBook,ParrBook,FetterBook,ReiningBook} % Moller-Plesset The workhorse of time-independent perturbation theory is most certainly M\o{}ller--Plesset (MP) perturbation theory \cite{Moller_1934} which remains one of the most popular methods for computing the electron correlation energy, an old yet important concept, first introduced by Wigner \cite{Wigner_1934} and later defined by L\"owdin. \cite{Lowdin_1958} In this approach, the exact electronic energy is estimated by constructing a perturbative correction on top of a mean-field Hartree--Fock (HF) approximation.\cite{SzaboBook} The popularity of MP theory stems from its black-box nature and relatively low computational scaling, making it easily applied in a broad range of molecular research. However, it is now widely understood that the series of MP approximations (defined for a given perturbation order $n$ as MP$n$) can show erratic, slow, or divergent behaviour that limit its systematic improvability.% \cite{Laidig_1985,Knowles_1985,Handy_1985,Gill_1986,Laidig_1987,Nobes_1987,Gill_1988,Gill_1988a,Lepetit_1988} As a result, practical applications typically employ only the lowest-order MP2 approach, while the successive MP3, MP4, and MP5 (and higher) terms are generally not considered to offer enough improvement to justify their increased cost. Turning the MP approximations into a convergent and systematically improvable series largely remains an open challenge. % COMPLEX PLANE Our conventional view of electronic structure theory is centred around the Hermitian notion of quantised energy levels, where the different electronic states of a molecular are discrete and energetically ordered. The lowest energy state defines the ground electronic state, while higher energy states represent electronic excited states. However, an entirely different perspective on quantisation can be found by analytically continuing quantum mechanics into the complex domain. In this inherently non-Hermitian framework, the energy levels emerge as individual \textit{sheets} of a complex multi-valued function and can be connected as one continuous \textit{Riemann surface}.\cite{BenderPTBook} This connection is possible because orderability of real numbers is lost when energies are extended to the complex domain. As a result, our quantised view of conventional quantum mechanics only arises from restricting our domain to Hermitian approximations. % NON-HERMITIAN HAMILTONIANS Non-Hermitian Hamiltonians already have a long history in quantum chemistry and have been extensively used to describe metastable resonance phenomena.\cite{MoiseyevBook} Through the methods of complex-scaling\cite{Moiseyev_1998} and complex absorbing potentials,\cite{Riss_1993,Ernzerhof_2006,Benda_2018} outgoing resonances can be stabilised as square-integrable wave functions with a complex energy that allows the resonance energy and lifetime to be computed. We refer the interested reader to the excellent book by Moiseyev for a general overview. \cite{MoiseyevBook} % EXCEPTIONAL POINTS The Riemann surface for the electronic energy $E(\lambda)$ with a coupling parameter $\lambda$ can be constructed by analytically continuing the function into the complex $\lambda$ domain. In the process, the ground and excited states become smoothly connected and form a continuous complex-valued energy surface. \textit{Exceptional points} (EPs) can exist on this energy surface, corresponding to branch point singularities where two (or more) states become exactly degenerate.% \cite{MoiseyevBook,Heiss_1988,Heiss_1990,Heiss_1999,Berry_2011,Heiss_2012,Heiss_2016,Benda_2018} While EPs can be considered as the non-Hermitian analogues of conical intersections,\cite{Yarkony_1996} the behaviour of their eigenvalues near a degeneracy could not be more different. Incredibly, following the eigenvalues around an EP leads to the interconversion of the degenerate states, and multiple loops around the EP are required to recover the initial energy.\cite{MoiseyevBook,Heiss_2016,Benda_2018} In contrast, encircling a conical intersection leaves the states unchanged. Furthermore, while the eigenvectors remain orthogonal at a conical intersection, the eigenvectors at an EP become identical and result in a \textit{self-orthogonal} state. \cite{MoiseyevBook} An EP effectively creates a ``portal'' between ground and excited-states in the complex plane.% \cite{Burton_2019,Burton_2019a} This transition between states has been experimentally observed in electronics, microwaves, mechanics, acoustics, atomic systems and optics.\cite{Bittner_2012,Chong_2011,Chtchelkatchev_2012,Doppler_2016,Guo_2009,Hang_2013,Liertzer_2012,Longhi_2010,Peng_2014, Peng_2014a,Regensburger_2012,Ruter_2010,Schindler_2011,Szameit_2011,Zhao_2010,Zheng_2013,Choi_2018,El-Ganainy_2018} % MP THEORY IN THE COMPLEX PLANE The MP energy correction can be considered as a function of the perturbation parameter $\lambda$. When the domain of $\lambda$ is extended to the complex plane, EPs can also occur in the MP energy. Although these EPs generally exist in the complex plane, their positions are intimately related to the convergence of the perturbation expansion on the real axis.% \cite{BenderBook,Olsen_1996,Olsen_2000,Olsen_2019,Mihalka_2017a,Mihalka_2017b,Mihalka_2019} Furthermore, the existence of an avoided crossing on the real axis is indicative of a nearby EP in the complex plane. Our aim in this article is to provide a comprehensive review of the fundamental relationship between EPs and the convergence properties of the MP series. In doing so, we will demonstrate how understanding the MP energy in the complex plane can be harnessed to significantly improve estimates of the exact energy using only the lowest-order terms in the MP series. The present review is organised as follows. In Sec.~\ref{sec:EPs}, we introduce key concepts, such as Rayleigh-Schr\"odinger perturbation theory and the mean-field HF approximation, and discuss their analytic continuation into the complex plane. Section \ref{sec:MP} deals with MP perturbation theory and we report an exhaustive historical overview of the various research activities that have been performed on the physics of singularities. We discuss several resummation techniques (such as Pad\'e and quadratic approximants) in Sec.~\ref{sec:Resummation}. Finally, we draw our conclusions in Sec.~\ref{sec:ccl}. For most of the concepts presented in this review, we report illustrative and pedagogical examples based on the ubiquitous Hubbard dimer, showing the amazing versatility of this simple yet powerful model system. %%%%%%%%%%%%%%%%%%%%%%% \section{Exceptional Points in Electronic Structure} \label{sec:EPs} %%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%% \subsection{Time-Independent Schr\"odinger Equation} \label{sec:TDSE} %%%%%%%%%%%%%%%%%%%%%%% Within the Born-Oppenheimer approximation, the exact molecular Hamiltonian with $\Ne$ electrons and $\Nn$ (clamped) nuclei is defined for a given nuclear framework as \begin{equation}\label{eq:ExactHamiltonian} \hH(\vb{R}) = - \frac{1}{2} \sum_{i}^{\Ne} \grad_i^2 - \sum_{i}^{\Ne} \sum_{A}^{\Nn} \frac{Z_A}{\abs{\vb{r}_i-\vb{R}_A}} + \sum_{i2t$, the closed-shell orbital restriction prevents RHF from modelling the correct physics with the two electrons on opposite 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]{fig3a} \subcaption{\label{subfig:UHF_cplx_angle}} \end{subfigure} \begin{subfigure}{0.49\textwidth} \includegraphics[height=0.65\textwidth]{fig3b} \subcaption{\label{subfig:UHF_cplx_energy}} \end{subfigure} \caption{% (\subref{subfig:UHF_cplx_angle}) Real component of the UHF angle $\ta^{\text{UHF}}$ for $\lambda \in \bbC$ in the Hubbard dimer for $U/t = 2$. Symmetry-broken solutions correspond to individual sheets and become equivalent at the \textit{quasi}-EP $\lambda_{\text{c}}$ (black dot). The RHF solution is independent of $\lambda$, giving the constant plane at $\pi/2$. (\subref{subfig:UHF_cplx_energy}) The corresponding HF energy surfaces show a non-analytic point at the \textit{quasi}-EP. \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 UHF solution appears with a lower energy than the RHF one. Note that the RHF wave function remains a genuine solution of the HF equations for $U \ge 2t$, but corresponds to a saddle point of the HF energy rather than a minimum. This critical point is analogous to the infamous Coulson--Fischer point identified in the hydrogen dimer.\cite{Coulson_1949} For $U \ge 2t$, the optimal orbital rotation angles for the UHF orbitals become \begin{subequations} \begin{align} \ta^\text{UHF} & = \arctan (-\frac{2t}{\sqrt{U^2 - 4t^2}}), \label{eq:ta_uhf} \\ \tb^\text{UHF} & = \arctan (+\frac{2t}{\sqrt{U^2 - 4t^2}}), \label{eq:tb_uhf} \end{align} \end{subequations} with the corresponding UHF ground-state energy (Fig.~\ref{fig:HF_real}) \begin{equation} E_\text{UHF} \equiv E_\text{HF}(\ta^\text{UHF}, \tb^\text{UHF}) = - \frac{2t^2}{U}. \end{equation} Time-reversal symmetry dictates that this UHF wave function must be degenerate with its spin-flipped pair, obtained by swapping $\ta^{\text{UHF}}$ and $\tb^{\text{UHF}}$ in Eqs.~\eqref{eq:ta_uhf} and \eqref{eq:tb_uhf}. This type of symmetry breaking is also called a spin-density wave in the physics community as the system ``oscillates'' between the two symmetry-broken configurations. \cite{GiulianiBook} Symmetry breaking can also occur in RHF theory when a charge-density wave is formed from an oscillation between the two closed-shell configurations with both electrons localised on one site or the other.\cite{StuberPaldus,Fukutome_1981} %============================================================% \subsection{Self-Consistency as a Perturbation} %OR {Complex adiabatic connection} %============================================================% % INTRODUCE PARAMETRISED FOCK HAMILTONIAN 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{Roothaan_1951,Hall_1951} Alternatively, the non-linear terms arising from the Coulomb and exchange operators can be considered as a perturbation from the core Hamiltonian \eqref{eq:Hcore} by introducing the transformation $U \to \lambda\, U$, giving the parametrised Fock operator \begin{equation} \Hat{f}(\vb{x} ; \lambda) = \Hat{h}(\vb{x}) + \lambda\, \Hat{v}_\text{HF}(\vb{x}). \end{equation} The orbitals in the reference problem $\lambda=0$ correspond to the symmetry-pure eigenfunctions of the one-electron core Hamiltonian, while self-consistent solutions at $\lambda = 1$ represent the orbitals of the true HF solution. % INTRODUCE COMPLEX ANALYTIC-CONTINUATION For real $\lambda$, the self-consistent HF energies at given (real) $U$ and $t$ values in the Hubbard dimer directly mirror the energies shown in Fig.~\ref{fig:HF_real}, with coalesence points at \begin{equation} \lambda_{\text{c}} = \pm \frac{2t}{U}. \label{eq:scaled_fock} \end{equation} 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 the holomorphic HF approach.\cite{Hiscock_2014,Burton_2016,Burton_2018} Remarkably, the coalescence point in this analytic continuation emerges as a \textit{quasi}-EP on the real $\lambda$ axis (Fig.~\ref{fig:HF_cplx}), where the different HF solutions become equivalent but not self-orthogonal.\cite{Burton_2019} By analogy with perturbation theory, the regime where this \textit{quasi}-EP occurs within $\lambda_{\text{c}} \le 1$ can be interpreted as an indication that the symmetry-pure reference orbitals no longer provide a qualitatively 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 do not provide a good representation of the HF ground state. 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. % COMPLEX ADIABATIC CONNECTION We have recently shown that the complex scaled Fock operator \eqref{eq:scaled_fock} also allows states of different symmetries to be interconverted by following a well-defined contour in the complex $\lambda$-plane.\cite{Burton_2019} 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} a ground-state wave function can be ``morphed'' into an excited-state wave function via a stationary path of HF solutions. This novel approach to identifying excited-state wave functions demonstrates the fundamental role of \textit{quasi}-EPs in determining the behaviour of the HF approximation. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \section{M{\o}ller--Plesset Perturbation Theory in the Complex Plane} \label{sec:MP} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %=====================================================% \subsection{Background Theory} %=====================================================% In electronic structure, the HF Hamiltonian \eqref{eq:HFHamiltonian} is often used as the zeroth-order Hamiltonian to define M\o{}ller--Plesset (MP) perturbation theory.\cite{Moller_1934} This approach can recover a large proportion of the electron correlation energy,\cite{Lowdin_1955a,Lowdin_1955b,Lowdin_1955c} and provides the foundation for numerous post-HF approximations. With the MP partitioning, the parametrised perturbation Hamiltonian becomes \begin{multline}\label{eq:MPHamiltonian} \hH(\lambda) = \sum_{i}^{N} \qty[ - \frac{\grad_i^2}{2} - \sum_{A}^{M} \frac{Z_A}{\abs{\vb{r}_i-\vb{R}_A}} ] \\ + (1-\lambda) \sum_{i}^{N} v^{\text{HF}}(\vb{x}_i) + \lambda\sum_{i 1$) and $4.5$ (where $r_c < 1$). 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}} \end{figure*} The behaviour of the RMP and UMP series observed in \ce{H2} can also be illustrated by considering the analytic Hubbard dimer with a complex-valued perturbation strength. In this system, the stretching of the \ce{H\bond{-}H} bond is directly mirrored by an increase in the ratio $U/t$. Using the ground-state RHF reference orbitals leads to the parametrised RMP Hamiltonian \begin{widetext} \begin{equation} \label{eq:H_RMP} \bH_\text{RMP}\qty(\lambda) = \begin{pmatrix} -2t + U - \lambda U/2 & 0 & 0 & \lambda U/2 \\ 0 & U - \lambda U/2 & \lambda U/2 & 0 \\ 0 & \lambda U/2 & U - \lambda U/2 & 0 \\ \lambda U/2 & 0 & 0 & 2t + U - \lambda U/2 \\ \end{pmatrix}, \end{equation} \end{widetext} which yields the ground-state energy \begin{equation} \label{eq:E0MP} E_{-}(\lambda) = U - \frac{\lambda U}{2} - \frac{1}{2} \sqrt{(4t)^2 + \lambda ^2 U^2}. \end{equation} From this expression, the EPs can be identified as $\lep = \pm \i 4t / U$, giving the radius of convergence \begin{equation} \rc = \abs{\frac{4t}{U}}. \end{equation} Remarkably, these EPs are identical to the exact EPs discussed in Sec.~\ref{sec:example}. The Taylor expansion of the RMP energy can then be evaluated to obtain the $k$th-order MP correction \begin{equation} E_\text{RMP}^{(k)} = U \delta_{0,k} - \frac{1}{2} \frac{U^k}{(4t)^{k-1}} \mqty( 1/2 \\ k/2). \end{equation} %%%%%%%%%%%%%%%%%%%%%%%%%%%%% % RADIUS OF CONVERGENCE PLOTS %%%%%%%%%%%%%%%%%%%%%%%%%%%%% \begin{figure}[htb] \includegraphics[width=\linewidth]{fig5} \caption{ Radius of convergence $r_c$ for the RMP ground state (red), the UMP ground state (blue), and the UMP excited state (orange) series as functions of the ratio $U/t$. \label{fig:RadConv}} \end{figure} %%%%%%%%%%%%%%%%%%%%%%%%%%%%% The RMP series is convergent for $U = 3.5\,t$ with $\rc > 1$, as illustrated for the individual terms at each order of perturbation in Fig.~\ref{subfig:RMP_cvg}. In contrast, for $U = 4.5t$ one finds $\rc < 1$, and the RMP series becomes divergent. The corresponding Riemann surfaces for $U = 3.5\,t$ and $4.5\,t$ are shown in Figs.~\ref{subfig:RMP_3.5} and \ref{subfig:RMP_4.5}, respectively, with the single EP at $\lep$ (black dot) and the radius of convergence indicated by the vertical cylinder of unit radius. For the divergent case, the $\lep$ lies inside this cylinder of convergence, while in the convergent case $\lep$ lies outside this cylinder. In both cases, the EP connects the ground state with the doubly-excited state, and thus the convergence behaviour for the two states using the ground-state RHF orbitals is identical. %%% FIG 3 %%% \begin{figure*} \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth]{fig6a} \subcaption{\label{subfig:UMP_3} $U/t = 3$} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth]{fig6b} \subcaption{\label{subfig:UMP_cvg}} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth]{fig6c} \subcaption{\label{subfig:UMP_7} $U/t = 7$} \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 $7$. 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}} \end{figure*} The behaviour of the UMP series is more subtle than the RMP series as the spin-contamination in the wave function introduces additional coupling between the singly- and doubly-excited configurations. Using the ground-state UHF reference orbitals in the Hubbard dimer yields the parametrised UMP Hamiltonian \begin{widetext} \begin{equation} \label{eq:H_UMP} \bH_\text{UMP}\qty(\lambda) = \begin{pmatrix} -2t^2 \lambda/U & 0 & 0 & 2t^2 \lambda/U \\ 0 & U - 2t^2 \lambda/U & 2t^2\lambda/U & 2t \sqrt{U^2 - (2t)^2} \lambda/U \\ 0 & 2t^2\lambda/U & U - 2t^2 \lambda/U & -2t \sqrt{U^2 - (2t)^2} \lambda/U \\ 2t^2 \lambda/U & 2t \sqrt{U^2 - (2t)^2} \lambda/U & -2t \sqrt{U^2 - (2t)^2} \lambda/U & 2U(1-\lambda) + 6t^2\lambda/U \\ \end{pmatrix}. \end{equation} \end{widetext} While a closed-form expression for the ground-state energy exists, it is cumbersome and we eschew reporting it. Instead, the radius of convergence of the UMP series can be obtained numerically as a function of $U/t$, as shown in Fig.~\ref{fig:RadConv}. These numerical values reveal that the UMP ground-state series has $\rc > 1$ for all $U/t$ and always converges. However, in the strong correlation limit (large $U/t$), this radius of convergence tends to unity, indicating that the convergence of the corresponding UMP series becomes increasingly slow. Furthermore, the doubly-excited state using the ground-state UHF orbitals has $\rc < 1$ for almost any value of $U/t$, reaching the limiting value of $1/2$ for $U/t \to \infty$. Hence, the excited-state UMP series will always diverge. % DISCUSSION OF UMP RIEMANN SURFACES The convergence behaviour can be further elucidated by considering the full structure of the UMP energies in the complex $\lambda$-plane (see Figs.~\ref{subfig:UMP_3} and \ref{subfig:UMP_7}). These Riemann surfaces are illustrated for $U = 3t$ and $7t$ alongside the perturbation terms at each order in Fig.~\ref{subfig:UMP_cvg}. At $U = 3t$, the RMP series is convergent, while RMP becomes divergent for $U=7t$. The ground-state UMP expansion is convergent in both cases, although the rate of convergence is significantly slower for larger $U/t$ as the radius of convergence becomes increasingly close to one (Fig.~\ref{fig:RadConv}). % EFFECT OF SYMMETRY BREAKING As the UHF orbitals break the spin symmetry, new coupling terms emerge between the electronic states that cause fundamental changes to the structure of EPs in the complex $\lambda$-plane. For example, while the RMP energy shows only one EP between the ground state and the doubly-excited state (Fig.~\ref{fig:RMP}), the UMP energy has two EPs: one connecting the ground state with the singly-excited open-shell singlet, and the other connecting this single excitation to the doubly-excited second excitation (Fig.~\ref{fig:UMP}). This new ground-state EP always appears outside the unit cylinder and guarantees convergence of the ground-state energy. However, the excited-state EP is moved within the unit cylinder and causes the convergence of the excited-state UMP series to deteriorate. Our interpretation of this effect is that the symmetry-broken orbital optimisation has redistributed the strong coupling between the ground- and doubly-excited states into weaker couplings between all states, and has thus sacrificed convergence of the excited-state series so that the ground-state convergence can be maximised. Since the UHF ground state already provides a good approximation to the exact energy, the ground-state sheet of the UMP energy is relatively flat and the corresponding EP in the Hubbard dimer always lies outside the unit cylinder. The slow convergence observed in stretched \ce{H2}\cite{Gill_1988} can then be seen as this EP moves increasingly close to the unit cylinder at large $U/t$ and $\rc$ approaches one (from above). Furthermore, the majority of the UMP expansion in this regime is concerned with removing spin-contamination from the wave function rather than improving the energy. It is well-known that the spin-projection needed to remove spin-contamination can require non-linear combinations of highly-excited determinants,\cite{Lowdin_1955c} and thus it is not surprising that this process proceeds very slowly as the perturbation order is increased. %==========================================% \subsection{Classifying Types of Convergence} % Behaviour} % Further insights from a two-state model} %==========================================% % CREMER AND HE As computational implementations of higher-order MP terms improved, the systematic investigation of convergence behaviour in a broader class of molecules became possible. Cremer and He introduced an efficient MP6 approach and used it to analyse the RMP convergence of 29 atomic and molecular systems with respect to the FCI energy.\cite{Cremer_1996} They established two general classes: ``class A'' systems that exhibit monotonic convergence; and ``class B'' systems for which convergence is erratic after initial oscillations. By analysing the different cluster contributions to the MP energy terms, they proposed that class A systems generally include well-separated and weakly correlated electron pairs, while class B systems are characterised by dense electron clustering in one or more spatial regions.\cite{Cremer_1996} In class A systems, they showed that the majority of the correlation energy arises from pair correlation, with little contribution from triple excitations. On the other hand, triple excitations have an important contribution in class B systems, including providing orbital relaxation, and these contributions lead to oscillations of the total correlation energy. Using these classifications, Cremer and He then introduced simple extrapolation formulas for estimating the exact correlation energy $\Delta E$ using terms up to MP6\cite{Cremer_1996} \begin{subequations} \begin{align} \Delta E_{\text{A}} &= \Emp^{(2)} + \Emp^{(3)} + \Emp^{(4)} + \frac{\Emp^{(5)}}{1 - (\Emp^{(6)} / \Emp^{(5)})}, \\[5pt] \Delta E_{\text{B}} &= \Emp^{(2)} + \Emp^{(3)} + \qty(\Emp^{(4)} + \Emp^{(5)}) \exp(\Emp^{(6)} / \Emp^{(5)}). \end{align} \end{subequations} These class-specific formulas reduced the mean absolute error from the FCI correlation energy by a factor of four compared to previous class-independent extrapolations, highlighting how one can leverage a deeper understanding of MP convergence to improve estimates of the correlation energy at lower computational costs. In Sec.~\ref{sec:Resummation}, we consider more advanced extrapolation routines that take account of EPs in the complex $\lambda$-plane. In the late 90's, Olsen \etal\ discovered an even more concerning behaviour of the MP series. \cite{Olsen_1996} They showed that the series could be divergent even in systems that were considered to be well understood, such as \ce{Ne} or the \ce{HF} molecule. \cite{Olsen_1996, Christiansen_1996} Cremer and He had already studied these two systems and classified them as \textit{class B} systems.\cite{Cremer_1996} However, Olsen and co-workers performed their analysis in larger basis sets containing diffuse functions, finding that the corresponding MP series becomes divergent at (very) high order. The discovery of this divergent behaviour is particularly worrying as large basis sets are required to get meaningful and accurate energies.\cite{Loos_2019d,Giner_2019} Furthermore, diffuse functions are particularly important for anions and/or Rydberg excited states, where the wave function is inherently more diffuse than the ground state.\cite{Loos_2018a,Loos_2020a} Olsen \etal\ investigated the causes of these divergences and the different types of convergence by analysing the relation between the dominant singularity (\ie, the closest singularity to the origin) and the convergence behaviour of the series.\cite{Olsen_2000} Their analysis is based on Darboux's theorem: \cite{Goodson_2011} \begin{quote} \textit{``In the limit of large order, the series coefficients become equivalent to the Taylor series coefficients of the singularity closest to the origin. ''} \end{quote} Following this theory, a singularity in the unit circle is designated as an intruder state, with a front-door (or back-door) intruder state if the real part of the singularity is positive (or negative). Using their observations in Ref.~\onlinecite{Olsen_1996}, Olsen and collaborators proposed a simple method that performs a scan of the real axis to detect the avoided crossing responsible for the dominant singularities in the complex plane. \cite{Olsen_2000} By modelling this avoided crossing using a two-state Hamiltonian, one can obtain an approximation for the dominant singularities as the EPs of the two-state matrix \begin{equation} \label{eq:Olsen_2x2} \underbrace{\mqty(\alpha & \delta \\ \delta & \beta )}_{\bH} = \underbrace{\mqty(\alpha + \alpha_{\text{s}} & 0 \\ 0 & \beta + \beta_{\text{s}} )}_{\bH^{(0)}} + \underbrace{\mqty( -\alpha_{\text{s}} & \delta \\ \delta & - \beta_{\text{s}})}_{\bV}, \end{equation} where the diagonal matrix is the unperturbed Hamiltonian matrix $\bH^{(0)}$ with level shifts $\alpha_{\text{s}}$ and $\beta_{\text{s}}$, and $\bV$ represents the perturbation. The authors first considered molecules with low-lying doubly-excited states with the same spatial and spin symmetry as the ground state. \cite{Olsen_2000} In these systems, the exact wave function has a non-negligible contribution from the doubly-excited states, and thus the low-lying excited states are likely to become intruder states. For \ce{CH_2} in a diffuse, yet rather small basis set, the series is convergent at least up to the 50th order, and the dominant singularity lies close (but outside) the unit circle, causing slow convergence of the series. These intruder-state effects are analogous to the EP that dictates the convergence behaviour of the RMP series for the Hubbard dimer (Fig.~\ref{fig:RMP}). Furthermore, the authors demonstrated that the divergence for \ce{Ne} is due to a back-door intruder state that arise when the ground state undergoes sharp avoided crossings with highly diffuse excited states. This divergence is related to a more fundamental critical point in the MP energy surface that we will discuss in Sec.~\ref{sec:MP_critical_point}. Finally, Ref.~\onlinecite{Olsen_1996} proved that the extrapolation formulas of Cremer and He \cite{Cremer_1996} are not mathematically motivated when considering the complex singularities causing the divergence, and therefore cannot be applied for all systems. For example, the \ce{HF} molecule contains both back-door intruder states and low-lying doubly-excited states that result in alternating terms up to 10th order. The series becomes monotonically convergent at higher orders since the two pairs of singularities are approximately the same distance from the origin. More recently, this two-state model has been extended to non-symmetric Hamiltonians as\cite{Olsen_2019} \begin{equation} \underbrace{\mqty(\alpha & \delta_1 \\ \delta_2 & \beta)}_{\bH} = \underbrace{\mqty(\alpha & 0 \\ 0 & \beta + \gamma )}_{\bH^{(0)}} + \underbrace{\mqty( 0 & \delta_2 \\ \delta_1 & - \gamma)}_{\bV}. \end{equation} This extension allows various choices of perturbation to be analysed, including coupled cluster perturbation expansions \cite{Pawlowski_2019a,Pawlowski_2019b,Pawlowski_2019c,Pawlowski_2019d,Pawlowski_2019e} and other non-Hermitian perturbation methods. Note that new forms of perturbation expansions only occur when the sign of $\delta_1$ and $\delta_2$ differ. Using this non-Hermitian two-state model, the convergence of a perturbation series can be characterised according to a so-called ``archetype'' that defines the overall ``shape'' of the energy convergence.\cite{Olsen_2019} For Hermitian Hamiltonians, these archetypes can be subdivided into five classes (zigzag, interspersed zigzag, triadic, ripples, and geometric), while two additional archetypes (zigzag-geometric and convex-geometric) are observed in non-Hermitian Hamiltonians. % The geometric archetype appears to be the most common for MP expansions,\cite{Olsen_2019} but the ripples archetype corresponds to some of the early examples of MP convergence. \cite{Handy_1985,Lepetit_1988,Leininger_2000} The three remaining Hermitian archetypes seem to be rarely observed in MP perturbation theory. In contrast, the non-Hermitian coupled cluster perturbation theory,% \cite{Pawlowski_2019a,Pawlowski_2019b,Pawlowski_2019c,Pawlowski_2019d,Pawlowski_2019e} exhibits a range of archetypes including the interspersed zigzag, triadic, ripple, geometric, and zigzag-geometric forms. This analysis highlights the importance of the primary critical point in controlling the high-order convergence, regardless of whether this point is inside or outside the complex unit circle. \cite{Handy_1985,Olsen_2000} %======================================= \subsection{M{\o}ller--Plesset Critical Point} \label{sec:MP_critical_point} %======================================= % STILLINGER INTRODUCES THE CRITICAL POINT In the early 2000's, Stillinger reconsidered the mathematical origin behind the divergent series with odd-even sign alternation.\cite{Stillinger_2000} This type of convergence behaviour corresponds to Cremer and He's class B systems with closely spaced electron pairs and includes \ce{Ne}, \ce{HF}, \ce{F-}, and \ce{H2O}.\cite{Cremer_1996} Stillinger proposed that these series diverge due to a dominant singularity on the negative real $\lambda$ axis, corresponding to a multielectron autoionisation threshold.\cite{Stillinger_2000} To understand Stillinger's argument, consider the parametrised MP Hamiltonian in the form \begin{multline} \label{eq:HamiltonianStillinger} \hH(\lambda) = \sum_{i}^{\Ne} \Bigg[ \overbrace{-\frac{1}{2}\grad_i^2 - \sum_{A}^{\Nn} \frac{Z_A}{\abs{\vb{r}_i-\vb{R}_A}}}^{\text{independent of $\lambda$}} \\ + \underbrace{(1-\lambda)v^{\text{HF}}(\vb{x}_i)}_{\text{repulsive for $\lambda < 1$}} + \underbrace{\lambda\sum_{i 0$. The reference Slater determinant for a doubly-occupied atom can be represented using RHF orbitals [see Eq.~\eqref{eq:RHF_orbs}] with $\theta_{\alpha}^{\text{RHF}} = \theta_{\beta}^{\text{RHF}} = 0$, which corresponds to strictly localising the two electrons on the left site. %and energy %\begin{equation} % E_\text{HF}(0, 0) = \frac{1}{2} (2 U - 4 \epsilon). %\end{equation} With this representation, the parametrised asymmetric RMP Hamiltonian becomes \begin{widetext} \begin{equation} \label{eq:H_asym} \bH_\text{asym}\qty(\lambda) = \begin{pmatrix} 2(U-\epsilon) - \lambda U & -\lambda t & -\lambda t & 0 \\ -\lambda t & (U-\epsilon) - \lambda U & 0 & -\lambda t \\ -\lambda t & 0 & (U-\epsilon) -\lambda U & -\lambda t \\ 0 & -\lambda t & -\lambda t & \lambda U \\ \end{pmatrix}. \end{equation} \end{widetext} % DERIVING BEHAVIOUR OF THE CRITICAL SITE For the ghost site to perfectly represent ionised electrons, the hopping term between the two sites must vanish (\ie, $t=0$). This limit corresponds to the dissociative regime in the asymmetric Hubbard dimer as discussed in Ref.~\onlinecite{Carrascal_2018}, and the RMP energies become \begin{subequations} \begin{align} E_{-} &= 2(U - \epsilon) - \lambda U, \\ E_{\text{S}} &= (U - \epsilon) - \lambda U, \\ E_{+} &= U \lambda, \end{align} \end{subequations} as shown in Fig.~\ref{subfig:rmp_cp} (dashed lines). The RMP critical point then corresponds to the intersection $E_{-} = E_{+}$, giving the critical $\lambda$ value \begin{equation} \lc = 1 - \frac{\epsilon}{U}. \end{equation} Clearly the radius of convergence $\rc = \abs{\lc}$ is controlled directly by the ratio $\epsilon / U$, with a convergent RMP series occurring for $\epsilon > 2 U$. The on-site repulsion $U$ controls the strength of the HF potential localised around the ``atomic site'', with a stronger repulsion encouraging the electrons to be ionised at a less negative value of $\lambda$. Large $U$ can be physically interpreted as strong electron repulsion effects in electron dense molecules. In contrast, smaller $\epsilon$ gives a weaker attraction to the atomic site, representing strong screening of the nuclear attraction by core and valence electrons, and again a less negative $\lambda$ is required for ionisation to occur. Both of these factors are common in atoms on the right-hand side of the periodic table, \eg\ \ce{F}, \ce{O}, \ce{Ne}. Molecules containing these atoms are therefore often class $\beta$ systems with a divergent RMP series due to the MP critical point. \cite{Goodson_2004,Sergeev_2006} % EXACT VERSUS APPROXIMATE The critical point in the exact case $t=0$ lies on the negative real $\lambda$ axis (Fig.~\ref{subfig:rmp_cp}: dashed lines), mirroring the behaviour of a quantum phase transition.\cite{Kais_2006} However, in practical calculations performed with a finite basis set, the critical point is modelled as a cluster of branch points close to the real axis. The use of a finite basis can be modelled in the asymmetric dimer by making the second site a less idealised destination for the ionised electrons with a non-zero (yet small) hopping term $t$. Taking the value $t=0.1$ (Fig.~\ref{subfig:rmp_cp}: solid lines), the critical point becomes a sharp avoided crossing with a complex-conjugate pair of EPs close to the real axis (Fig.~\ref{subfig:rmp_cp_surf}). In the limit $t \to 0$, these EPs approach the real axis (Fig.~\ref{subfig:rmp_ep_to_cp}), mirroring Sergeev's discussion on finite basis set representations of the MP critical point.\cite{Sergeev_2006} %------------------------------------------------------------------% % Figure on the UMP critical point %------------------------------------------------------------------% \begin{figure*}[t] \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth,trim={0pt 5pt -10pt 15pt},clip]{fig8a} \subcaption{\label{subfig:ump_cp}} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth]{fig8b} \subcaption{\label{subfig:ump_cp_surf}} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.75\textwidth]{fig8c} \subcaption{\label{subfig:ump_ep_to_cp}} \end{subfigure} % \includegraphics[height=0.65\textwidth,trim={0pt 5pt 0pt 15pt}, clip]{ump_critical_point} \caption{% The UMP ground-state EP in the symmetric Hubbard dimer becomes a critical point in the strong correlation limit (\ie, large $U/t$). (\subref{subfig:ump_cp}) As $U/t$ increases, the avoided crossing on the real $\lambda$ axis becomes increasingly sharp. (\subref{subfig:ump_cp_surf}) Complex energy surfaces for $U = 5t$. (\subref{subfig:ump_ep_to_cp}) Convergence of the EPs at $\lep$ onto the real axis for $U/t \to \infty$. %mirrors the formation of the RMP critical point and other QPTs in the complete basis set limit. \label{fig:UMP_cp}} \end{figure*} %------------------------------------------------------------------% % RELATIONSHIP BETWEEN QPT AND UMP Returning to the symmetric Hubbard dimer, we showed in Sec.~\ref{sec:spin_cont} that the slow convergence of the strongly correlated UMP series was due to a complex-conjugate pair of EPs just outside the radius of convergence. These EPs have positive real components and small imaginary components (see Fig.~\ref{fig:UMP}), suggesting a potential connection to MP critical points and QPTs (see Sec.~\ref{sec:MP_critical_point}). For $\lambda>1$, the HF potential becomes an attractive component in Stillinger's Hamiltonian displayed in Eq.~\eqref{eq:HamiltonianStillinger}, while the explicit electron-electron interaction becomes increasingly repulsive. Closed--shell critical points along the positive real $\lambda$ axis then represent points where the two-electron repulsion overcomes the attractive HF potential and a single electron dissociates from the molecule (see Ref.~\onlinecite{Sergeev_2006}) In contrast, symmetry-breaking in the UMP reference creates different HF potentials for the spin-up and spin-down electrons. Consider one of the two reference UHF solutions where the spin-up and spin-down electrons are localised on the left and right sites respectively. The spin-up HF potential will then be a repulsive interaction from the spin-down electron density that is centred around the right site (and vice-versa). As $\lambda$ becomes greater than 1 and the HF potentials become attractive, there will be a sudden driving force for the electrons to swap sites. This swapping process can also be represented as a double excitation, and thus an avoided crossing will occur for $\lambda \geq 1$ (Fig.~\ref{subfig:ump_cp}). While this appears to be an avoided crossing between the ground and first-excited state, the presence of an earlier excited-state avoided crossing means that the first-excited state qualitatively represents the reference double excitation for $\lambda > 1/2$. % SHARPNESS AND QPT The ``sharpness'' of the avoided crossing is controlled by the correlation strength $U/t$. For small $U/t$, the HF potentials will be weak and the electrons will delocalise over the two sites, both in the UHF reference and the exact wave function. This delocalisation dampens the electron swapping process and leads to a ``shallow'' avoided crossing that corresponds to EPs with non-zero imaginary components (solid lines in Fig.~\ref{subfig:ump_cp}). As $U/t$ becomes larger, the HF potentials become stronger and the on-site repulsion dominates the hopping term to make electron delocalisation less favourable. In other words, the electrons localise on individual sites to form a Wigner crystal. These effects create a stronger driving force for the electrons to swap sites until eventually this swapping occurs exactly at $\lambda = 1$. In this limit, the ground-state EPs approach the real axis (Fig.~\ref{subfig:ump_ep_to_cp}) and the avoided crossing creates a gradient discontinuity in the ground-state energy (dashed lines in Fig.~\ref{subfig:ump_cp}). We therefore find that, in the strong correlation limit, the symmetry-broken ground-state EP becomes a new type of MP critical point and represents a QPT as the perturbation parameter $\lambda$ is varied. Furthermore, this argument explains why the dominant UMP singularity lies so close, but always outside, the radius of convergence (see Fig.~\ref{fig:RadConv}). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \section{Resummation Methods} \label{sec:Resummation} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%% \begin{figure*} \includegraphics[height=0.23\textheight]{fig9a} \includegraphics[height=0.23\textheight]{fig9b} \caption{\label{fig:PadeRMP} RMP ground-state energy as a function of $\lambda$ obtained using various resummation techniques at $U/t = 3.5$ (left) and $U/t = 4.5$ (right).} \end{figure*} %%%%%%%%%%%%%%%%% %As frequently claimed by Carl Bender, It is frequently stated that \textit{``the most stupid thing that one can do with a series is to sum it.''} Nonetheless, quantum chemists are basically doing this on a daily basis. As we have seen throughout this review, the MP series can often show erratic, slow, or divergent behaviour. In these cases, estimating the correlation energy by simply summing successive low-order terms is almost guaranteed to fail. Here, we discuss alternative tools that can be used to sum slowly convergent or divergent series. These so-called ``resummation'' techniques form a vast field of research and thus we will provide details for only the most relevant methods. We refer the interested reader to more specialised reviews for additional information.% \cite{Goodson_2011,Goodson_2019} %==========================================% \subsection{Pad\'e Approximant} %==========================================% The failure of a Taylor series for correctly modelling the MP energy function $E(\lambda)$ arises because one is trying to model a complicated function containing multiple branches, branch points and singularities using a simple polynomial of finite order. A truncated Taylor series can only predict a single sheet and does not have enough flexibility to adequately describe functions such as the MP energy. Alternatively, the description of complex energy functions can be significantly improved by introducing Pad\'e approximants, \cite{Pade_1892} and related techniques. \cite{BakerBook,BenderBook} A Pad\'e approximant can be considered as the best approximation of a function by a rational function of given order. More specifically, a $[d_A/d_B]$ Pad\'e approximant is defined as \begin{equation} \label{eq:PadeApp} E_{[d_A/d_B]}(\lambda) = \frac{A(\lambda)}{B(\lambda)} = \frac{\sum_{k=0}^{d_A} a_k\, \lambda^k}{1 + \sum_{k=1}^{d_B} b_k\, \lambda^k}, \end{equation} where the coefficients of the polynomials $A(\lambda)$ and $B(\lambda)$ are determined by collecting terms for each power of $\lambda$. Pad\'e approximants are extremely useful in many areas of physics and chemistry\cite{Loos_2013,Pavlyukh_2017,Tarantino_2019,Gluzman_2020} as they can model poles, which appear at the roots of $B(\lambda)$. However, they are unable to model functions with square-root branch points (which are ubiquitous in the singularity structure of a typical perturbative treatment) and more complicated functional forms appearing at critical points (where the nature of the solution undergoes a sudden transition). Despite this limitation, the successive diagonal Pad\'e approximants (\ie, $d_A = d_B $) often define a convergent perturbation series in cases where the Taylor series expansion diverges. \begin{table}[b] \caption{RMP ground-state energy estimate at $\lambda = 1$ provided by various truncated Taylor series and Pad\'e approximants at $U/t = 3.5$ and $4.5$. We also report the distance of the closest pole to the origin $\abs{\lc}$ provided by the diagonal Pad\'e approximants. \label{tab:PadeRMP}} \begin{ruledtabular} \begin{tabular}{lccccc} & & \mc{2}{c}{$\abs{\lc}$} & \mc{2}{c}{$E_{-}(\lambda = 1)$} \\ \cline{3-4} \cline{5-6} Method & Degree & $U/t = 3.5$ & $U/t = 4.5$ & $U/t = 3.5$ & $U/t = 4.5$ \\ \hline Taylor & 2 & & & $-1.01563$ & $-1.01563$ \\ & 3 & & & $-1.01563$ & $-1.01563$ \\ & 4 & & & $-0.86908$ & $-0.61517$ \\ & 5 & & & $-0.86908$ & $-0.61517$ \\ & 6 & & & $-0.92518$ & $-0.86858$ \\ \hline Pad\'e & [1/1] & $2.29$ & $1.78$ & $-1.61111$ & $-2.64286$ \\ & [2/2] & $2.29$ & $1.78$ & $-0.82124$ & $-0.48446$ \\ & [3/3] & $1.73$ & $1.34$ & $-0.91995$ & $-0.81929$ \\ & [4/4] & $1.47$ & $1.14$ & $-0.90579$ & $-0.74866$ \\ & [5/5] & $1.35$ & $1.05$ & $-0.90778$ & $-0.76277$ \\ \hline Exact & & $1.14$ & $0.89$ & $-0.90754$ & $-0.76040$ \\ \end{tabular} \end{ruledtabular} \end{table} Figure~\ref{fig:PadeRMP} illustrates the improvement provided by diagonal Pad\'e approximants compared to the usual Taylor expansion in cases where the RMP series of the Hubbard dimer converges ($U/t = 3.5$) and diverges ($U/t = 4.5$). More quantitatively, Table \ref{tab:PadeRMP} gathers estimates of the RMP ground-state energy at $\lambda = 1$ provided by various truncated Taylor series and Pad\'e approximants for these two values of the ratio $U/t$. While the truncated Taylor series converges laboriously to the exact energy as the truncation degree increases at $U/t = 3.5$, the Pad\'e approximants yield much more accurate results. Furthermore, the distance of the closest pole to the origin $\abs{\lc}$ in the Pad\'e approximants indicate that they provide a relatively good approximation to the position of the true branch point singularity in the RMP energy. For $U/t = 4.5$, the Taylor series expansion performs worse and eventually diverges, while the Pad\'e approximants still offer relatively accurate energies and recovers a convergent series. %%%%%%%%%%%%%%%%% \begin{figure}[t] \includegraphics[width=\linewidth]{fig10} \caption{\label{fig:QuadUMP} UMP energies as a function of $\lambda$ obtained using various resummation techniques at $U/t = 3$.} \end{figure} %%%%%%%%%%%%%%%%% We can expect the UMP energy function to be much more challenging to model properly as it contains three connected branches (see Figs.~\ref{subfig:UMP_3} and \ref{subfig:UMP_7}). Figure~\ref{fig:QuadUMP} and Table~\ref{tab:QuadUMP} indicate that this is indeed the case. In particular, Fig.~\ref{fig:QuadUMP} illustrates that the Pad\'e approximants are trying to model the square root branch point that lies close to $\lambda = 1$ by placing a pole on the real axis (\eg, [3/3]) or with a very small imaginary component (\eg, [4/4]). The proximity of these poles to the physical point $\lambda = 1$ means that any error in the Pad\'e functional form becomes magnified in the estimate of the exact energy, as seen for the low-order approximants in Table~\ref{tab:QuadUMP}. However, with sufficiently high degree polynomials, one obtains accurate estimates for the position of the closest singularity and the ground-state energy at $\lambda = 1$, even in cases where the convergence of the UMP series is incredibly slow (see Fig.~\ref{subfig:UMP_cvg}). %==========================================% \subsection{Quadratic Approximant} %==========================================% Quadratic approximants are designed to model the singularity structure of the energy function $E(\lambda)$ via a generalised version of the square-root singularity expression \cite{Mayer_1985,Goodson_2011,Goodson_2019} \begin{equation} \label{eq:QuadApp} E(\lambda) = \frac{1}{2 Q(\lambda)} \qty[ P(\lambda) \pm \sqrt{P^2(\lambda) - 4 Q(\lambda) R(\lambda)} ], \end{equation} with the polynomials \begin{align} \label{eq:PQR} P(\lambda) & = \sum_{k=0}^{d_P} p_k \lambda^k, & Q(\lambda) & = \sum_{k=0}^{d_Q} q_k \lambda^k, & R(\lambda) & = \sum_{k=0}^{d_R} r_k \lambda^k, \end{align} defined such that $d_P + d_Q + d_R = n - 1$, and $n$ is the truncation order of the Taylor series of $E(\lambda)$. Recasting Eq.~\eqref{eq:QuadApp} as a second-order expression in $E(\lambda)$, \ie, \begin{equation} Q(\lambda) E^2(\lambda) - P(\lambda) E(\lambda) + R(\lambda) \sim \order*{\lambda^{n+1}}, \end{equation} and substituting $E(\lambda$) by its $n$th-order expansion and the polynomials by their respective expressions \eqref{eq:PQR} yields $n+1$ linear equations for the coefficients $p_k$, $q_k$, and $r_k$ (where we are free to assume that $q_0 = 1$). A quadratic approximant, characterised by the label $[d_P/d_Q,d_R]$, generates, by construction, $n_\text{bp} = \max(2d_p,d_q+d_r)$ branch points at the roots of the polynomial $P^2(\lambda) - 4 Q(\lambda) R(\lambda)$ and $d_q$ poles at the roots of $Q(\lambda)$. Generally, the diagonal sequence of quadratic approximant, \ie, $[0/0,0]$, $[1/0,0]$, $[1/0,1]$, $[1/1,1]$, $[2/1,1]$, is of particular interest as the order of the corresponding Taylor series increases on each step. However, while a quadratic approximant can reproduce multiple branch points, it can only describe a total of two branches. %\titou{Since every branch points must therefore correspond to a degeneracy of the same two branches,} This constraint can hamper the faithful description of more complicated singularity structures such as the MP energy surface. Despite this limitation, Ref.~\onlinecite{Goodson_2000a} demonstrates that quadratic approximants provide convergent results in the most divergent cases considered by Olsen and collaborators\cite{Christiansen_1996,Olsen_1996} and Leininger \etal \cite{Leininger_2000} As a note of caution, Ref.~\onlinecite{Goodson_2019} suggests that low-order quadratic approximants can struggle to correctly model the singularity structure when the energy function has poles in both the positive and negative half-planes. In such a scenario, the quadratic approximant will tend to place its branch points in-between, potentially introducing singularities quite close to the origin. The remedy for this problem involves applying a suitable transformation of the complex plane (such as a bilinear conformal mapping) which leaves the points at $\lambda = 0$ and $\lambda = 1$ unchanged. \cite{Feenberg_1956} \begin{table}[b] \caption{Estimate for the distance of the closest singularity (pole or branch point) to the origin $\abs{\lc}$ in the UMP energy function provided by various resummation techniques at $U/t = 3$ and $7$. The truncation degree of the Taylor expansion $n$ of $E(\lambda)$ and the number of branch points $n_\text{bp} = \max(2d_p,d_q+d_r)$ generated by the quadratic approximants are also reported. \label{tab:QuadUMP}} \begin{ruledtabular} \begin{tabular}{lccccccc} & & & & \mc{2}{c}{$\abs{\lc}$} & \mc{2}{c}{$E_{-}(\lambda = 1)$} \\ \cline{5-6}\cline{7-8} \mc{2}{c}{Method} & $n$ & $n_\text{bp}$ & $U/t = 3$ & $U/t = 7$ & $U/t = 3$ & $U/t = 7$ \\ \hline Taylor & & 2 & & & & $-0.74074$ & $-0.29155$ \\ & & 3 & & & & $-0.78189$ & $-0.29690$ \\ & & 4 & & & & $-0.82213$ & $-0.30225$ \\ & & 5 & & & & $-0.85769$ & $-0.30758$ \\ & & 6 & & & & $-0.88882$ & $-0.31289$ \\ \hline Pad\'e & [1/1] & 2 & & $9.000$ & $49.00$ & $-0.75000$ & $-0.29167$ \\ & [2/2] & 4 & & $0.974$ & $1.003$ & $\hphantom{-}0.75000$ & $-17.9375$ \\ & [3/3] & 6 & & $1.141$ & $1.004$ & $-1.10896$ & $-1.49856$ \\ & [4/4] & 8 & & $1.068$ & $1.003$ & $-0.85396$ & $-0.33596$ \\ & [5/5] & 10 & & $1.122$ & $1.004$ & $-0.97254$ & $-0.35513$ \\ \hline Quadratic & [2/1,2] & 6 & 4 & $1.086$ & $1.003$ & $-1.01009$ & $-0.53472$ \\ & [2/2,2] & 7 & 4 & $1.082$ & $1.003$ & $-1.00553$ & $-0.53463$ \\ & [3/2,2] & 8 & 6 & $1.082$ & $1.001$ & $-1.00568$ & $-0.52473$ \\ & [3/2,3] & 9 & 6 & $1.071$ & $1.002$ & $-0.99973$ & $-0.53102$ \\ & [3/3,3] & 10 & 6 & $1.071$ & $1.002$ & $-0.99966$ & $-0.53103$ \\[0.5ex] (pole-free) & [3/0,2] & 6 & 6 & $1.059$ & $1.003$ & $-1.13712$ & $-0.57199$ \\ & [3/0,3] & 7 & 6 & $1.073$ & $1.002$ & $-1.00335$ & $-0.53113$ \\ & [3/0,4] & 8 & 6 & $1.071$ & $1.002$ & $-1.00074$ & $-0.53116$ \\ & [3/0,5] & 9 & 6 & $1.070$ & $1.002$ & $-1.00042$ & $-0.53114$ \\ & [3/0,6] & 10 & 6 & $1.070$ & $1.002$ & $-1.00039$ & $-0.53113$ \\ \hline Exact & & & & $1.069$ & $1.002$ & $-1.00000$ & $-0.53113$ \\ \end{tabular} \end{ruledtabular} \end{table} \begin{figure*} \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.85\textwidth]{fig11a} \subcaption{\label{subfig:322quad} [3/2,2] Quadratic} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.85\textwidth]{fig11b} \subcaption{\label{subfig:exact} Exact} \end{subfigure} % \begin{subfigure}{0.32\textwidth} \includegraphics[height=0.85\textwidth]{fig11c} \subcaption{\label{subfig:304quad} [3/0,4] Quadratic} \end{subfigure} \caption{% Comparison of the [3/2,2] and [3/0,4] quadratic approximants with the exact UMP energy surface in the complex $\lambda$ plane with $U/t = 3$. Both quadratic approximants correspond to the same truncation degree of the Taylor series and model the branch points using a radicand polynomial of the same order. However, the [3/2,2] approximant introduces poles into the surface that limits it accuracy, while the [3/0,4] approximant is free of poles.} \label{fig:nopole_quad} \end{figure*} For the RMP series of the Hubbard dimer, the $[0/0,0]$ and $[1/0,0]$ quadratic approximant are quite poor approximations, but the $[1/0,1]$ version perfectly models the RMP energy function by predicting a single pair of EPs at $\lambda_\text{EP} = \pm \i 4t/U$. This is expected from the form of the RMP energy [see Eq.~\eqref{eq:E0MP}], which matches the ideal target for quadratic approximants. Furthermore, the greater flexibility of the diagonal quadratic approximants provides a significantly improved model of the UMP energy in comparison to the Pad\'e approximants or Taylor series. In particular, these quadratic approximants provide an effective model for the avoided crossings (Fig.~\ref{fig:QuadUMP}) and an improved estimate for the distance of the closest branch point to the origin. Table~\ref{tab:QuadUMP} shows that they provide remarkably accurate estimates of the ground-state energy at $\lambda = 1$. While the diagonal quadratic approximants provide significanty improved estimates of the ground-state energy, we can use our knowledge of the UMP singularity structure to develop even more accurate results. We have seen in previous sections that the UMP energy surface contains only square-root branch cuts that approach the real axis in the limit $U/t \to \infty$. Since there are no true poles on this surface, we can obtain more accurate quadratic approximants by taking $d_q = 0$ and increasing $d_r$ to retain equivalent accuracy in the square-root term [see Eq.\eqref{eq:QuadApp}]. Figure~\ref{fig:nopole_quad} illustrates this improvement for the pole-free [3/0,4] quadratic approximant compared to the [3/2,2] approximant with the same truncation degree in the Taylor expansion. Clearly, modelling the square-root branch point using $d_q = 2$ has the negative effect of introducing spurious poles in the energy, while focussing purely on the branch point with $d_q = 0$ leads to a significantly improved model. Table~\ref{tab:QuadUMP} shows that these pole-free quadratic approximants provide a rapidly convergent series with essentially exact energies at low order. Finally, to emphasise the improvement that can be gained by using either Pad\'e, diagonal quadratic, or pole-free quadratic approximants, we consider the energy and error obtained using only the first 10 terms of the UMP Taylor series in Table~\ref{tab:UMP_order10}. The accuracy of these approximants reinforces how our understanding of the MP energy surface in the complex plane can be leveraged to significantly improve estimates of the exact energy using low-order perturbation expansions. \begin{table}[h] \caption{ Estimate and associated error of the exact UMP energy at $U/t = 7$ for various approximants using up to ten terms in the Taylor expansion. \label{tab:UMP_order10}} \begin{ruledtabular} \begin{tabular}{lccc} \mc{2}{c}{Method} & $E_{-}(\lambda = 1)$ & \% Abs.\ Error \\ \hline Taylor & 10 & $-0.33338$ & $37.150$ \\ Pad\'e & [5/5] & $-0.35513$ & $33.140$ \\ Quadratic (diagonal) & [3/3,3] & $-0.53103$ & $\hphantom{0}0.019$ \\ Quadratic (pole-free)& [3/0,6] & $-0.53113$ & $\hphantom{0}0.005$ \\ \hline Exact & & $-0.53113$ & \\ \end{tabular} \end{ruledtabular} \end{table} %==========================================% \subsection{Shanks Transformation} \label{sec:Shanks} %==========================================% While the Pad\'e and quadratic approximants can yield a convergent series representation in cases where the standard MP series diverges, there is no guarantee that the rate of convergence will be fast enough for low-order approximations to be useful. However, these low-order partial sums or approximants often contain a remarkable amount of information that can be used to extract further information about the exact result. The Shanks transformation presents one approach for extracting this information and accelerating the rate of convergence of a sequence.\cite{Shanks_1955,BenderBook} Consider the partial sums $S_n = \sum_{k=0}^{n} s_k$ defined from the truncated summation of an infinite series $S = \sum_{k=0}^{\infty} s_k$. If the series converges, then the partial sums will tend to the exact result \begin{equation} \lim_{n \to \infty} S_n = S. \end{equation} The Shanks transformation attempts to generate increasingly accurate estimates of this limit by defining a new series as \begin{equation} T(S_n) = \frac{S_{n+1} S_{n-1} - S_{n}^2}{S_{n+1} + S_{n-1} - 2 S_{n}}. \end{equation} This series can converge faster than the original partial sums and can thus provide greater accuracy using only the first few terms in the series. However, it is only designed to accelerate converging partial sums with the approximate form \begin{equation} S_n \approx S + \alpha\,\beta^n. \end{equation} Furthermore, while this transformation can accelerate the convergence of a series, there is no guarantee that this acceleration will be fast enough to significantly improve the accuracy of low-order approximations. To the best of our knowledge, the Shanks transformation has never previously been applied to accelerate the convergence of the MP series. We have therefore applied it to the convergent Taylor series, Pad\'e approximants, and quadratic approximants for RMP and UMP in the symmetric Hubbard dimer. The UMP approximants converge too slowly for the Shanks transformation to provide any improvement, even in the case where the quadratic approximants are already very accurate. In contrast, acceleration of the diagonal Pad\'e approximants for the RMP cases can significantly improve the estimate of the energy using low-order perturbation terms, as shown in Table~\ref{tab:RMP_shank}. Even though the RMP series diverges at $U/t = 4.5$, the combination of diagonal Pad\'e approximants with the Shanks transformation reduces the absolute error in the best energy estimate to 0.002\,\% using only the first 10 terms in the Taylor series. This remarkable result indicates just how much information is contained in the first few terms of a perturbation series, even if it diverges. \begin{table}[th] \caption{ Acceleration of the diagonal Pad\'e approximant sequence for the RMP energy using the Shanks transformation. \label{tab:RMP_shank}} \begin{ruledtabular} \begin{tabular}{lcccc} & & & \mc{2}{c}{$E_{-}(\lambda = 1)$} \\ \cline{4-5} Method & Degree & Series Term & $U/t = 3.5$ & $U/t = 4.5$ \\ \hline Pad\'e & [1/1] & $S_1$ & $-1.61111$ & $-2.64286$ \\ & [2/2] & $S_2$ & $-0.82124$ & $-0.48446$ \\ & [3/3] & $S_3$ & $-0.91995$ & $-0.81929$ \\ & [4/4] & $S_4$ & $-0.90579$ & $-0.74866$ \\ & [5/5] & $S_5$ & $-0.90778$ & $-0.76277$ \\ \hline Shanks & & $T(S_2)$ & $-0.90898$ & $-0.77432$ \\ & & $T(S_3)$ & $-0.90757$ & $-0.76096$ \\ & & $T(S_4)$ & $-0.90753$ & $-0.76042$ \\ \hline Exact & & & $-0.90754$ & $-0.76040$ \\ \end{tabular} \end{ruledtabular} \end{table} %==========================================% \subsection{Analytic continuation} %==========================================% Recently, Mih\'alka \etal\ have studied the effect of different partitionings, such as MP or EN theory, on the position of branch points and the convergence properties of Rayleigh--Schr\"odinger perturbation theory\cite{Mihalka_2017b} (see also Ref.~\onlinecite{Surjan_2000}). Taking the equilibrium and stretched water structures as an example, they estimated the radius of convergence using quadratic Pad\'e approximants. The EN partitioning provided worse convergence properties than the MP partitioning, which is believed to be because the EN denominators are generally smaller than the MP denominators. To remedy the situation, they showed that introducing a suitably chosen level shift parameter can turn a divergent series into a convergent one by increasing the magnitude of these denominators.\cite{Mihalka_2017b} However, like the UMP series in stretched \ce{H2},\cite{Lepetit_1988} the cost of larger denominators is an overall slower rate of convergence. \begin{figure} \includegraphics[width=\linewidth]{fig12} \caption{% Comparison of the scaled RMP10 Taylor expansion with the exact RMP energy as a function of $\lambda$ for the symmetric Hubbard dimer at $U/t = 4$. The two functions correspond closely within the radius of convergence. } \label{fig:rmp_anal_cont} \end{figure} In a later study by the same group, they used analytic continuation techniques to resum a divergent MP series such as a stretched water molecule.\cite{Mihalka_2017a} Any MP series truncated at a given order $n$ can be used to define the scaled function \begin{equation} E_{\text{MP}n}(\lambda) = \sum_{k=0}^{n} \lambda^{k} E_\text{MP}^{(k)}. \end{equation} Reliable estimates of the energy can be obtained for values of $\lambda$ where the MP series is rapidly convergent (\ie, for $\abs{\lambda} < \rc$), as shown in Fig.~\ref{fig:rmp_anal_cont} for the RMP10 series of the symmetric Hubbard dimer with $U/t = 4.5$. These values can then be analytically continued using a polynomial- or Pad\'e-based fit to obtain an estimate of the exact energy at $\lambda = 1$. However, choosing the functional form for the best fit remains a difficult and subtle challenge. This technique was first generalised using complex scaling parameters to construct an analytic continuation by solving the Laplace equations.\cite{Surjan_2018} It was then further improved by introducing Cauchy's integral formula\cite{Mihalka_2019} \begin{equation} \label{eq:Cauchy} E(\lambda) = \frac{1}{2\pi \i} \oint_{\mathcal{C}} \frac{E(\lambda')}{\lambda' - \lambda}, \end{equation} which states that the value of the energy can be computed at $\lambda_1$ inside the complex contour $\mathcal{C}$ using only the values along the same contour. Starting from a set of points in a ``trusted'' region where the MP series is convergent, their approach self-consistently refines estimates of the $E(\lambda')$ values on a contour that includes the physical point $\lambda = 1$. The shape of this contour is arbitrary, but there must be no branch points or other singularities inside the contour. Once the contour values of $E(\lambda')$ are converged, Cauchy's integral formula Eq.~\eqref{eq:Cauchy} can be invoked to compute the value at $E(\lambda=1)$ and obtain a final estimate of the exact energy. The authors illustrate this protocol for the dissociation curve of \ce{LiH} and the stretched water molecule to obtain encouragingly accurate results.\cite{Mihalka_2019} %%%%%%%%%%%%%%%%%%%% \section{Conclusion} \label{sec:ccl} %%%%%%%%%%%%%%%%%%%% In order to model accurately chemical systems, one must choose, in an ever growing zoo of methods, which computational protocol is adapted to the system of interest. This choice can be, moreover, motivated by the type of properties that one is interested in. That means that one must understand the strengths and weaknesses of each method, \ie, why one method might fail in some cases and work beautifully in others. We have seen that for methods relying on perturbation theory, their successes and failures are directly connected to the position of singularities in the complex plane, known as exceptional points. After a short presentation of the fundamental notions of quantum chemistry in the complex plane, such as the mean-field Hartree--Fock approximation and Rayleigh--Schr\"odinger perturbation theory, we have provided an exhaustive historical overview of the various research activities that have been performed on the physics of singularities with a particular focus on M{\o}ller--Plesset perturbation theory. Seminal contributions from various research groups around the world have evidenced highly oscillatory, slowly convergent, or catastrophically divergent behaviour of the restricted and/or unrestricted MP perturbation series.% \cite{Laidig_1985,Knowles_1985,Handy_1985,Gill_1986,Laidig_1987,Nobes_1987,Gill_1988,Gill_1988a,Lepetit_1988} Later, these erratic behaviours were investigated and rationalised in terms of avoided crossings and singularities in the complex plane. In that regard, it is worth highlighting the key contribution of Cremer and He who proposed a classification of the types of convergence: \cite{Cremer_1996} ``class A'' systems that exhibit monotonic convergence, and ``class B'' systems for which convergence is erratic after initial oscillations. Further insights were brought thanks to a series of papers by Olsen and coworkers \cite{Christiansen_1996,Olsen_1996,Olsen_2000,Olsen_2019} where they employed a two-state model to dissect the various convergence behaviours of Hermitian and non-Hermitian perturbation series. Building on the careful mathematical analysis of Stillinger who showed that the mathematical origin behind the divergent series with odd-even sign alternation is due to a dominant singularity on the negative real $\lambda$ axis, \cite{Stillinger_2000} Sergeev and Goodson proposed a more refined singularity classification: $\alpha$ singularities which have ``large'' imaginary parts, and $\beta$ singularities which have very small imaginary parts. \cite{Goodson_2000a,Goodson_2000b,Goodson_2004,Sergeev_2005,Sergeev_2006} We have further highlighted that these so-called $\beta$ singularities are connected to quantum phase transitions and symmetry breaking. Finally, we have discussed several resummation techniques, such as Pad\'e and quadratic approximants, that can be used to improve energy estimates for both convergent and divergent series. However, it is worth mentioning that the construction of these approximants requires high-order MP coefficients which are quite expensive to compute in practice. The Shanks transformation presented in Sec.~\ref{sec:Shanks} can, in some cases, alleviate this issue. Most of the physical concepts and mathematical tools reviewed in the present manuscript has been illustrated on the symmetric (or asymmetric in one occasion) Hubbard dimer at half-filling. Although extremely simple, this clearly illustrates the obvious versatility of the Hubbard model to understand perturbation theory as well as other concepts such as Kohn-Sham density-functional theory (DFT), \cite{Carrascal_2015} linear-response theory, \cite{Carrascal_2018} many-body perturbation theory, \cite{Romaniello_2009,Romaniello_2012,DiSabatino_2015,Tarantino_2017}, DFT for ensembles, \cite{Deur_2017,Deur_2018,Senjean_2018,Sagredo_2018,Fromager_2020} thermal DFT, \cite{Smith_2016,Smith_2018} and many others. We believe that the Hubbard dimer could then be used for further developments and comprehension around perturbation theory. As a concluding remark and from a broader point of view, the present work shows that our understanding of the singularity structure of the energy is still incomplete. Yet, we hope that the present contribution will open new perspectives on the physics of exceptional points in electronic structure theory. %%%%%%%%%%%%%%%%%%%%%%%% \begin{acknowledgements} %%%%%%%%%%%%%%%%%%%%%%%% This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant agreement No.~863481). HGAB gratefully acknowledges New College, Oxford for funding through the Astor Junior Research Fellowship. %%%%%%%%%%%%%%%%%%%%%% \end{acknowledgements} %%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%% \bibliography{EPAWTFT} %%%%%%%%%%%%%%%%%%%%%% \end{document}