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Pierre-Francois Loos 2021-05-10 09:55:05 +02:00
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\affiliation{\LCPQ} \affiliation{\LCPQ}
\author{Anthony Scemama} \author{Anthony Scemama}
\affiliation{\LCPQ} \affiliation{\LCPQ}
\author{Michel Caffarel}
\affiliation{\LCPQ}
\author{Denis Jacquemin} \author{Denis Jacquemin}
\affiliation{\CEISAM} \affiliation{\CEISAM}
\author{Pierre-Fran\c{c}ois Loos} \author{Pierre-Fran\c{c}ois Loos}
@ -62,16 +64,62 @@ The performance of the ground-state gold standard CCSD(T) is also investigated.
% Title % Title
\maketitle \maketitle
%%%%%%%%%%%%%%%%%%%%%%%%%
\section{Introduction} \section{Introduction}
%%%%%%%%%%%%%%%%%%%%%%%%%
Electronic structure theory relies heavily on approximations.
Loosely speaking, to make any theory useful, three main approximations must be enforced.
The first fundamental approximation, known as the Born-Oppenheimer approximation, usually consists in assuming that the motion of nuclei and electrons are decoupled.
The second central approximation which makes calculations feasable by a computer is the basis set approximation where one introduces a set of pre-defined basis functions to represent the many-electron wave function of the system.
In most molecular calculations, a set of one-electron, atom-centered gaussian basis functions are introduced to expand the so-called one-electron molecular orbitals which are then used to build the many-electron Slater determinants.
The third and most relevant approximation in the present context is the ansatz (or form) of the electronic wave function $\Psi$.
For example, in configuration interaction (CI) methods, the wave function is expanded as a linear combination of Slater determinants, while in (single-reference) coupled-cluster (CC) theory, \cite{Cizek_1966,Paldus_1972,Crawford_2000,Bartlett_2007,Shavitt_2009} a reference Slater determinant $\Psi_0$ [usually taken as the Hartree-Fock (HF) wave function] is multiplied by a wave operator defined as the exponentiated excitation operator
\begin{equation}
\Hat{T} = \sum_{k=1}^N \Hat{T}_k
\end{equation}
where $N$ is the number of electrons.
The truncation of $\Hat{T}$ defines as well-defined hierarchy of non-variational and size-extensive methods with improved accuracy.
CC with singles and doubles (CCSD), \cite{Cizek_1966,Purvis_1982}
CC with singles, doubles, and triples (CCSDT), \cite{Noga_1987a,Scuseria_1988}
CC with singles, doubles, triples, and quadruples (CCSDTQ), \cite{Oliphant_1991,Kucharski_1992} and
with corresponding computational scalings of $\order*{N^{6}}$, $\order*{N^{8}}$, and $\order*{N^{10}}$, respectively (where $N$ denotes the number of orbitals).
CC2, \cite{Christiansen_1995a}
CC3, \cite{Christiansen_1995b,Koch_1997} and
CC4 \cite{Kallay_2005} series of models which have been introduced by the Aarhus group in the context of CC response theory. \cite{Christiansen_1998}
These iterative methods scale as $\order*{N^{5}}$, $\order*{N^{7}}$, and $\order*{N^{9}}$, respectively, and can be seen as cheaper approximations of CCSD, CCSDT, and CCSDTQ, by skipping the most expensive terms and avoiding the storage of the higher-excitation amplitudes.
A similar systematic truncation strategy can be applied to CI methods leading to alternative family of methods known as CISD, CISDT, CISDTQ, \ldots~which consists in increasing the maximum excitation degree of the determinants tkaen into account.
Except for full CI for which all determinants with excitation degree up to $N$ are taken into account, truncated CI methods are variational but lack size-consistency.
The non-variationnality of CC methods being less of an issue than the size-inconsistency of the CI methods, it is fair to say that truncated CC methods have naturally overshadowed truncated CI methods in the electronic structure landscape.
M{\o}ller-Plesset pertrubation theory \cite{Moller_1934}
MP3 \cite{Pople_1976}
MP4 \cite{Krishnan_1980}
MP5 \cite{Kucharski_1989}
MP6 \cite{He_1996a,He_1996b}
CCSD(T) \cite{Raghavachari_1989} is the gold-standard
Reviews. \cite{Crawford_2000,Piecuch_2002,Bartlett_2007,Shavitt_2009}
Coupled-cluster methods have been particularly successful for small- and medium-sized molecules properties
\cite{Kallay_2003,Kallay_2004a,Gauss_2006,Kallay_2006,Gauss_2009}
%%% FIG 1 %%%
\begin{figure*} \begin{figure*}
\includegraphics[width=\linewidth]{mol} \includegraphics[width=\linewidth]{mol}
\caption{ \caption{
Five-membered rings (top) and six-membered rings (bottom) considered in this study. Five-membered rings (top) and six-membered rings (bottom) considered in this study.
\label{fig:mol}} \label{fig:mol}}
\end{figure*} \end{figure*}
%%% FIG 1 %%%
%%%%%%%%%%%%%%%%%%%%%%%%%
\section{Computational details} \section{Computational details}
%%%%%%%%%%%%%%%%%%%%%%%%%
The geometries of the twelve systems considered in the present study have been all obtained at the CC3/aug-cc-pVTZ level of geometry and have been extracted from a previous study. \cite{Loos_2020a} The geometries of the twelve systems considered in the present study have been all obtained at the CC3/aug-cc-pVTZ level of geometry and have been extracted from a previous study. \cite{Loos_2020a}
The MP2, MP3, MP4, CC2, CC3, CC4, CCSD, CCSDT, and CCSDTQ calculations have been performed with Cfour, \cite{cfour} while the CCSD(T) and MP5 calculations have been performed in Gaussian 09. \cite{g09} The MP2, MP3, MP4, CC2, CC3, CC4, CCSD, CCSDT, and CCSDTQ calculations have been performed with Cfour, \cite{cfour} while the CCSD(T) and MP5 calculations have been performed in Gaussian 09. \cite{g09}
For all these calculations, we consider Dunning's correlation-consistent double-$\zeta$ basis (cc-pVDZ) which consists of Hilbert space sizes ranging from $10^{20}$ (for thiophene) to $10^{36}$ (for benzene). For all these calculations, we consider Dunning's correlation-consistent double-$\zeta$ basis (cc-pVDZ) which consists of Hilbert space sizes ranging from $10^{20}$ (for thiophene) to $10^{36}$ (for benzene).
@ -161,7 +209,7 @@ We have found that $\expval*{\Hat{S}^2}$ is, nonetheless, very close to zero for
\begin{acknowledgements} \begin{acknowledgements}
This work was performed using HPC resources from GENCI-TGCC (2020-gen1738) and from CALMIP (Toulouse) under allocation 2020-18005. This work was performed using HPC resources from GENCI-TGCC (2020-gen1738) and from CALMIP (Toulouse) under allocation 2020-18005.
PFL and AS have received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant agreement No.~863481). PFL, AS, and MC have received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant agreement No.~863481).
\end{acknowledgements} \end{acknowledgements}
\section*{Data availability statement} \section*{Data availability statement}