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\begin { document}
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\title { A weight-dependent local correlation density-functional approximation for ensembles}
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\author { Pierre-Fran\c { c} ois Loos}
\email { loos@irsamc.ups-tlse.fr}
\affiliation { \LCPQ }
\author { Emmanuel Fromager}
\email { fromagere@unistra.fr}
\affiliation { \LCQ }
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\begin { abstract}
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We report a local, weight-dependent correlation density-functional approximation that incorporates information about both ground and excited states in the context of density-functional theory for ensembles (eDFT).
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This density-functional approximation for ensembles is specially
designed for the computation of single and double excitations within
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Gross--Oliveira--Kohn (GOK) DFT (\textit { i.e.} , eDFT for neutral
excitations), and can be seen as a natural extension of the ubiquitous local-density approximation in the context of ensembles.
The resulting density-functional approximation, based on both finite and infinite uniform electron gas models, automatically incorporates the infamous derivative discontinuity contributions to the excitation energies through its explicit ensemble weight dependence.
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Its accuracy is illustrated by computing single and double excitations in one-dimensional many-electron systems in the weak, intermediate and strong correlation regimes.
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Although the present weight-dependent functional has been specifically
designed for one-dimensional systems, the methodology proposed here is
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general, \ie , directly applicable to the construction of weight-dependent functionals for realistic three-dimensional systems, such as molecules and solids.
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\end { abstract}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\maketitle
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section { Introduction}
\label { sec:intro}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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Over the last two decades, density-functional theory (DFT)
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\cite { Hohenberg_ 1964,Kohn_ 1965,ParrBook} has become the method of choice for
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modeling the electronic structure of large molecular systems and
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materials.
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The main reason is that, within DFT, the quantum contributions to the
electronic repulsion energy --- the so-called exchange-correlation (xc)
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energy --- is rewritten as a functional of the electron density $ \n { } { } \equiv \n { } { } ( \br { } ) $ , the latter being a much simpler quantity than the many-electron wave function.
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The complexity of the many-body problem is then transferred to the xc
density functional.
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Despite its success, the standard Kohn-Sham (KS) formulation of DFT \cite { Kohn_ 1965} (KS-DFT) suffers, in practice, from various deficiencies. \cite { Woodcock_ 2002, Tozer_ 2003,Tozer_ 1999,Dreuw_ 2003,Sobolewski_ 2003,Dreuw_ 2004,Tozer_ 1998,Tozer_ 2000,Casida_ 1998,Casida_ 2000,Tapavicza_ 2008,Levine_ 2006}
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The description of strongly multiconfigurational ground states (often
referred to as ``strong correlation problem'') still remains a
challenge. \cite { Gori-Giorgi_ 2010,Fromager_ 2015,Gagliardi_ 2017}
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Another issue, which is partly connected to the previous one, is the
description of low-lying quasi-degenerate states.
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The standard approach for modeling excited states in a DFT framework is
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linear-response time-dependent DFT (TDDFT). \cite { Runge_ 1984,Casida,Casida_ 2012}
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In this case, the electronic spectrum relies on the (unperturbed) pure-ground-state KS picture, which may break down when electron correlation is strong.
Moreover, in exact TDDFT, the xc energy is in fact an xc { \it action} \cite { Vignale_ 2008} which is a
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functional of the time-dependent density $ \n { } { } \equiv \n { } { } ( \br ,t ) $ and, as
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such, it should incorporate memory effects. Standard implementations of TDDFT rely on
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the adiabatic approximation where these effects are neglected. \cite { Dreuw_ 2005} In other
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words, the xc functional is assumed to be local in time. \cite { Casida,Casida_ 2012}
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As a result, double electronic excitations (where two electrons are simultaneously promoted by a single photon) are completely absent from the TDDFT spectrum, thus reducing further the applicability of TDDFT. \cite { Maitra_ 2004,Cave_ 2004,Mazur_ 2009,Romaniello_ 2009a,Sangalli_ 2011,Mazur_ 2011,Huix-Rotllant_ 2011,Elliott_ 2011,Maitra_ 2012,Sundstrom_ 2014,Loos_ 2019}
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When affordable (\ie , for relatively small molecules), time-independent
state-averaged wave function methods
\cite { Roos,Andersson_ 1990,Angeli_ 2001a,Angeli_ 2001b,Angeli_ 2002,Helgakerbook} can be employed to fix the various issues mentioned above.
The basic idea is to describe a finite (canonical) ensemble of ground
and excited states altogether, \ie , with the same set of orbitals.
Interestingly, a similar approach exists in DFT. Referred to as
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Gross--Oliveira--Kohn (GOK) DFT, \cite { Gross_ 1988a,Gross_ 1988b,Oliveira_ 1988} it was proposed at the end of the 80's as a generalization
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of Theophilou's DFT for equiensembles. \cite { Theophilou_ 1979}
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In GOK-DFT, the ensemble xc energy is a functional of the
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density { \it and} a
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function of the ensemble weights. Note that, unlike in conventional
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Boltzmann ensembles, \cite { Pastorczak_ 2013} the ensemble weights (each state in the ensemble
is assigned a given and fixed weight) are allowed to vary
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independently in a GOK ensemble.
The weight dependence of the xc functional plays a crucial role in the
calculation of excitation energies.
\cite { Gross_ 1988b,Yang_ 2014,Deur_ 2017,Deur_ 2019,Senjean_ 2018,Senjean_ 2020}
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It actually accounts for the derivative discontinuity contribution to energy gaps. \cite { Levy_ 1995, Perdew_ 1983}
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%\titou{Shall we further discuss the derivative discontinuity? Why is it important and where is it coming from?}
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Even though GOK-DFT is in principle able to
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describe near-degenerate situations and multiple-electron excitation
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processes, it has not
been given much attention until quite recently. \cite { Franck_ 2014,Borgoo_ 2015,Kazaryan_ 2008,Gould_ 2013,Gould_ 2014,Filatov_ 2015,Filatov_ 2015b,Filatov_ 2015c,Gould_ 2017,Deur_ 2017,Gould_ 2018,Gould_ 2019,Sagredo_ 2018,Ayers_ 2018,Deur_ 2018,Deur_ 2019,Kraisler_ 2013, Kraisler_ 2014,Alam_ 2016,Alam_ 2017,Nagy_ 1998,Nagy_ 2001,Nagy_ 2005,Pastorczak_ 2013,Pastorczak_ 2014,Pribram-Jones_ 2014,Yang_ 2013a,Yang_ 2014,Yang_ 2017,Senjean_ 2015,Senjean_ 2016,Senjean_ 2018,Smith_ 2016}
One of the reason is the lack, not to say the absence, of reliable
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density-functional approximations for ensembles.
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The most recent works dealing with this particular issue are still fundamental and
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exploratory, as they rely either on simple (but nontrivial) model
systems
\cite { Carrascal_ 2015,Deur_ 2017,Deur_ 2018,Deur_ 2019,Senjean_ 2015,Senjean_ 2016,Senjean_ 2018,Sagredo_ 2018,Senjean_ 2020,Fromager_ 2020,Gould_ 2019}
or atoms. \cite { Yang_ 2014,Yang_ 2017,Gould_ 2019_ insights}
Despite all these efforts, it is still unclear how weight dependencies
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can be incorporated into density-functional approximations. This problem is actually central not
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only in GOK-DFT but also in conventional (ground-state) DFT as the infamous derivative
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discontinuity problem that occurs when crossing an integral number of
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electrons can be recast into a weight-dependent ensemble
one. \cite { Senjean_ 2018,Senjean_ 2020}
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The present work is an attempt to address the ensemble weight dependence problem
in GOK-DFT,
with the ambition to turn the theory, in the forthcoming future, into a
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(low-cost) practical computational method for modeling excited states in molecules and extended systems.
Starting from the ubiquitous local-density approximation (LDA), we
design a weight-dependent ensemble correction based on a finite uniform
electron gas from which density-functional excitation energies can be
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extracted. The present density-functional approximation for ensembles, which can be seen as a natural
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extension of the LDA, will be referred to as eLDA in the remaining of this paper.
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As a proof of concept, we apply this general strategy to
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ensemble correlation energies (that we combine with
ensemble exact exchange energies) in the particular case of
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\emph { strict} one-dimensional (1D)
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spin-polarized systems. \cite { Loos_ 2012, Loos_ 2013a, Loos_ 2014a, Loos_ 2014b}
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In other words, the Coulomb interaction used in this work corresponds to
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particles which are \emph { strictly} restricted to move within a 1D sub-space of three-dimensional space.
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Despite their simplicity, 1D models are scrutinized as paradigms for quasi-1D materials \cite { Schulz_ 1993, Fogler_ 2005a} such as carbon nanotubes \cite { Bockrath_ 1999, Ishii_ 2003, Deshpande_ 2008} or nanowires. \cite { Meyer_ 2009, Deshpande_ 2010}
%Early models of 1D atoms using this interaction have been used to study the effects of external fields upon Rydberg atoms \cite{Burnett_1993, Mayle_2007} and the dynamics of surface-state electrons in liquid helium. \cite{Nieto_2000, Patil_2001}
This description of 1D systems also has interesting connections with the exotic chemistry of ultra-high magnetic fields (such as those in white dwarf stars), where the electronic cloud is dramatically compressed perpendicular to the magnetic field. \cite { Schmelcher_ 1990, Lange_ 2012, Schmelcher_ 2012}
In these extreme conditions, where magnetic effects compete with Coulombic forces, entirely new bonding paradigms emerge. \cite { Schmelcher_ 1990, Schmelcher_ 1997, Tellgren_ 2008, Tellgren_ 2009, Lange_ 2012, Schmelcher_ 2012, Boblest_ 2014, Stopkowicz_ 2015}
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The paper is organized as follows.
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Exact and approximate formulations of GOK-DFT are discussed in Sec.~\ref { sec:eDFT} ,
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with a particular emphasis on the extraction of individual energy levels.
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In Sec.~\ref { sec:eDFA} , we detail the construction of the
weight-dependent local correlation functional specially designed for the
computation of single and double excitations within GOK-DFT.
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Computational details needed to reproduce the results of the present work are reported in Sec.~\ref { sec:comp_ details} .
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In Sec.~\ref { sec:res} , we illustrate the accuracy of the present eLDA functional by computing single and double excitations in 1D many-electron systems in the weak, intermediate and strong correlation regimes.
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Finally, we draw our conclusions in Sec.~\ref { sec:conclusion} .
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Atomic units are used throughout.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section { Theory}
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\label { sec:eDFT}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\subsection { GOK-DFT} \label { subsec:gokdft}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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In this section we give a brief review of GOK-DFT and discuss the
extraction of individual energy levels \cite { Deur_ 2019,Fromager_ 2020} with a particular focus on exact
individual exchange energies.
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Let us start by introducing the GOK ensemble energy \cite { Gross_ 1988a}
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\beq \label { eq:exact_ GOK_ ens_ ener}
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\E { } { \bw } =\sum _ { K \geq 0} \ew { K} \E { } { (K)} ,
\eeq
where the $ K $ th energy level $ \E { } { ( K ) } $ [$ K = 0 $ refers to the ground state] is the eigenvalue of the electronic Hamiltonian $ \hH = \hh + \hWee $ , where
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\beq
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\hh = \sum _ { i=1} ^ \nEl \qty [ -\frac{1}{2} \nabla_{i}^2 + \vne(\br{i}) ]
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\eeq
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is the one-electron operator describing kinetic and nuclear attraction energies, and $ \hat { W } _ { \rm ee } $ is the electron repulsion operator.
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The (positive) ensemble weights $ \ew { K } $ decrease with increasing index $ K $ .
They are normalized, \ie ,
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\beq \label { eq:weight_ norm_ cond}
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\ew { 0} = 1 - \sum _ { K>0} \ew { K} ,
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\eeq
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so that only the weights $ \bw \equiv \qty ( \ew { 1 } , \ew { 2 } , \ldots , \ew { K } , \ldots ) $ assigned to the excited states can vary independently.
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For simplicity we will assume in the following that the energies are not degenerate.
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Note that the theory can be extended to multiplets simply by assigning the same ensemble weight to all degenerate states.\cite { Gross_ 1988b}
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In the KS formulation of GOK-DFT, { which is simply referred to as
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KS ensemble DFT (KS-eDFT) in the following} , the ensemble energy is determined variationally as follows:\cite { Gross_ 1988b}
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\beq \label { eq:var_ ener_ gokdft}
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\E { } { \bw }
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= \min _ { \opGam { \bw } }
\qty {
\Tr [\opGam{\bw} \hh] + \E { Hx} { \bw } \qty [\n{\opGam{\bw}}{}] + \E { c} { \bw } \qty [\n{\opGam{\bw}}{}]
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} ,
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\eeq
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where $ \Tr $ denotes the trace and the trial ensemble density matrix operator reads
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\beq
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\opGam { \bw } =\sum _ { K \geq 0} \ew { K} \dyad * { \Det { (K)} } .
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\eeq
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The KS determinants [or configuration state functions~\cite { Gould_ 2017} ]
$ \Det { ( K ) } $ are all constructed from the same set of ensemble KS
orbitals that are variationally optimized.
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The trial ensemble density in Eq.~\eqref { eq:var_ ener_ gokdft} is simply
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the weighted sum of the individual KS densities, \ie ,
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\beq \label { eq:KS_ ens_ density}
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\n { \opGam { \bw } } { } (\br { } ) = \sum _ { K\geq 0} \ew { K} \n { \Det { (K)} } { } (\br { } ).
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\eeq
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As readily seen from Eq.~\eqref { eq:var_ ener_ gokdft} , both Hartree-exchange (Hx) and correlation (c) energies are described with density functionals that are \textit { weight dependent} .
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We focus in the following on the (exact) Hx part, which is defined as~\cite { Gould_ 2017}
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\beq \label { eq:exact_ ens_ Hx}
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\E { Hx} { \bw } [\n { } { } ]=\sum _ { K \geq 0} \ew { K} \mel * { \Det { (K),\bw } [\n { } { } ]} { \hWee } { \Det { (K),\bw } [\n { } { } ]} ,
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\eeq
where the KS wavefunctions fulfill the ensemble density constraint
\beq
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\sum _ { K\geq 0} \ew { K} \n { \Det { (K),\bw } [\n { } { } ]} { } (\br { } ) = \n { } { } (\br { } ).
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\eeq
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The (approximate) description of the correlation part is discussed in
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Sec.~\ref { sec:eDFA} .
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In practice, the ensemble energy is not the most interesting quantity, and one is more concerned with excitation energies or individual energy levels (for geometry optimizations, for example).
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As pointed out recently in Ref.~\onlinecite { Deur_ 2019} , the latter can be extracted
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exactly from a single ensemble calculation as follows:
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\beq \label { eq:indiv_ ener_ from_ ens}
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\E { } { (I)} = \E { } { \bw } + \sum _ { K>0} \qty (\delta _ { IK} - \ew { K} )
\pdv { \E { } { \bw } } { \ew { K} } ,
\eeq
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where, according to the normalization condition of Eq.~\eqref { eq:weight_ norm_ cond} ,
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\beq
\pdv { \E { } { \bw } } { \ew { K} } = \E { } { (K)} -
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\E { } { (0)} \equiv \Ex { } { (K)}
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\eeq
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corresponds to the $ K $ th excitation energy.
According to the { \it variational} ensemble energy expression of
Eq.~\eqref { eq:var_ ener_ gokdft} , the derivative with respect to $ \ew { K } $
can be evaluated from the minimizing weight-dependent KS wavefunctions
$ \Det { ( K ) } \equiv \Det { ( K ) , \bw } $ as follows:
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\beq \label { eq:deriv_ Ew_ wk}
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\begin { split}
\pdv { \E { } { \bw } } { \ew { K} }
& = \mel * { \Det { (K)} } { \hh } { \Det { (K)} } -\mel * { \Det { (0)} } { \hh } { \Det { (0)} }
\\
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& + \Bigg \{ \int \fdv { \E { Hx} { \bw } [\n { } { } ]} { \n { } { } (\br { } )} \qty [ \n{\Det{(K)}}{}(\br{}) - \n{\Det{(0)}}{}(\br{}) ] d\br { }
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+ \pdv { \E { Hx} { \bw } [\n { } { } ]} { \ew { K} }
\\
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& + \int \fdv { \E { c} { \bw } [n]} { \n { } { } (\br { } )} \qty [ \n{\Det{(K)}}{}(\br{}) - \n{\Det{(0)}}{}(\br{}) ] d\br { }
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+ \pdv { \E { c} { \bw } [n]} { \ew { K} }
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\Bigg \} _ { \n { } { } = \n { \opGam { \bw } } { } } .
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\end { split}
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\eeq
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The Hx contribution from Eq.~\eqref { eq:deriv_ Ew_ wk} can be recast as
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\beq \label { eq:_ deriv_ wk_ Hx}
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\left .
\pdv { } { \xi _ K} \qty (\E { Hx} { \bxi } [\n { } { \bxi ,\bxi } ]
- \E { Hx} { \bw } [\n { } { \bw ,\bxi } ] )
\right |_ { \bxi =\bw } ,
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\eeq
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where $ \bxi \equiv ( \xi _ 1 , \xi _ 2 , \ldots , \xi _ K, \ldots ) $ and the
auxiliary double-weight ensemble density reads
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\beq
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\n { } { \bw ,\bxi } (\br { } ) = \sum _ { K\geq 0} \ew { K} \n { \Det { (K),\bxi } } { } (\br { } ).
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\eeq
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Since, for given ensemble weights $ \bw $ and $ \bxi $ , the ensemble
densities $ \n { } { \bxi , \bxi } $ and $ \n { } { \bw , \bxi } $ are obtained from the \textit { same} KS potential (which is unique up to a constant), it comes
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from the exact expression in Eq.~\eqref { eq:exact_ ens_ Hx} that
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\beq
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\E { Hx} { \bxi } [\n { } { \bxi ,\bxi } ] = \sum _ { K \geq 0} \xi _ K \mel * { \Det { (K),\bxi } } { \hWee } { \Det { (K),\bxi } } ,
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\eeq
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and
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\beq
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\E { Hx} { \bw } [\n { } { \bw ,\bxi } ] = \sum _ { K \geq 0} \ew { K} \mel * { \Det { (K),\bxi } } { \hWee } { \Det { (K),\bxi } } .
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\eeq
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This yields, according to Eqs.~\eqref { eq:deriv_ Ew_ wk} and \eqref { eq:_ deriv_ wk_ Hx} , the simplified expression
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\beq \label { eq:deriv_ Ew_ wk_ simplified}
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\begin { split}
\pdv { \E { } { \bw } } { \ew { K} }
& = \mel * { \Det { (K)} } { \hH } { \Det { (K)} }
- \mel * { \Det { (0)} } { \hH } { \Det { (0)} }
\\
& + \qty {
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\int \fdv { \E { c} { \bw } [\n { } { } ]} { \n { } { } ({ \br { } } )}
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\qty [ \n{\Det{(K)}}{}(\br{}) - \n{\Det{(0)}}{}(\br{}) ]
+
\pdv { \E { c} { \bw } [\n { } { } ]} { \ew { K} }
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} _ { \n { } { } = \n { \opGam { \bw } } { } } d\br { } .
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\end { split}
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\eeq
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Since, according to Eqs.~\eqref { eq:var_ ener_ gokdft} and \eqref { eq:exact_ ens_ Hx} , the ensemble energy can be evaluated as
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\beq
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\E { } { \bw } = \sum _ { K \geq 0} \ew { K} \mel * { \Det { (K)} } { \hH } { \Det { (K)} } + \E { c} { \bw } [\n { \opGam { \bw } } { } ],
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\eeq
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with $ \Det { ( K ) } = \Det { ( K ) , \bw } $ [note that, when the minimum is reached in Eq.~\eqref { eq:var_ ener_ gokdft} , $ \n { \opGam { \bw } } { } = \n { } { \bw , \bw } $ ],
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we finally recover from Eqs.~\eqref { eq:KS_ ens_ density} and
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\eqref { eq:indiv_ ener_ from_ ens} the { \it exact} expression of Ref.~\onlinecite { Fromager_ 2020} for the $ I $ th energy level:
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\beq \label { eq:exact_ ener_ level_ dets}
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\begin { split}
\E { } { (I)}
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& = \mel * { \Det { (I)} } { \hH } { \Det { (I)} } + \E { c} { { \bw } } [\n { \opGam { \bw } } { } ]
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\\
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& + \int \fdv { \E { c} { \bw } [\n { \opGam { \bw } } { } ]} { \n { } { } (\br { } )}
\qty [ \n{\Det{(I)}}{}(\br{}) - \n{\opGam{\bw}}{}(\br{}) ] d\br { }
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\\
& +
\sum _ { K>0} \qty (\delta _ { IK} - \ew { K} )
\left .
\pdv { \E { c} { \bw } [\n { } { } ]} { \ew { K} }
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\right |_ { \n { } { } = \n { \opGam { \bw } } { } } .
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\end { split}
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\eeq
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Note that, when $ \bw = 0 $ , the ensemble correlation functional reduces to the
conventional (ground-state) correlation functional $ E _ { \rm c } [ n ] $ . As a
result, the regular KS-DFT expression is recovered from
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Eq.~\eqref { eq:exact_ ener_ level_ dets} for the ground-state energy:
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\beq
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\E { } { (0)} =\mel * { \Det { (0)} } { \hH } { \Det { (0)} } +
\E { c} { } [\n { \Det { (0)} } { } ],
\eeq
or, equivalently,
\beq \label { eq:gs_ ener_ level_ gs_ lim}
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\E { } { (0)} =\mel * { \Det { (0)} } { \hat { H} [\n { \Det { (0)} } { } ]} { \Det { (0)} }
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,
\eeq
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where the density-functional Hamiltonian reads
\beq \label { eq:dens_ func_ Hamilt}
\hat { H} [n]=\hH +
\sum ^ N_ { i=1} \left (\fdv { \E { c} { } [n]} { \n { } { } (\br { i} )}
+C_ { \rm c} [n]
\right ),
\eeq
and
\beq \label { eq:corr_ LZ_ shift}
C_ { \rm c} [n]=\dfrac { \E { c} { } [n]
-\int
\fdv { \E { c} { } [n]} { \n { } { } (\br { } )} n(\br { } )d\br { } } { \int n(\br { } )d\br { } }
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\eeq
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is the correlation component of
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Levy--Zahariev's constant shift in potential.\cite { Levy_ 2014}
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Similarly, the excited-state ($ I> 0 $ ) energy level expressions
can be recast as follows:
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\beq \label { eq:excited_ ener_ level_ gs_ lim}
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\E { } { (I)}
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= \mel * { \Det { (I)} } { \hat { H} [\n { \Det { (0)} } { } ]} { \Det { (I)} }
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+
\left .
\pdv { \E { c} { \bw } [\n { \Det { (0)} } { } ]} { \ew { I} }
\right |_ { \bw =0} .
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\eeq
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As readily seen from Eqs.~\eqref { eq:dens_ func_ Hamilt} and
\eqref { eq:corr_ LZ_ shift} , introducing any constant shift $ \delta
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\E { c} { } [\n { \Det { (0)} } { } ]/\delta n({ \bf r} )\rightarrow \delta
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\E { c} { } [\n { \Det { (0)} } { } ]/\delta n({ \bf r} )+C$ into the correlation
potential leaves the density-functional Hamiltonian $ \hat { H } [ n ] $ (and
therefore the individual energy levels) unchanged. As a result, in
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this context,
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the correlation derivative discontinuities induced by the
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excitation process~\cite { Levy_ 1995} will be fully described by the
correlation ensemble derivatives [second term on the right-hand side of
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Eq.~\eqref { eq:excited_ ener_ level_ gs_ lim} ].
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%%%%%%%%%%%%%%%%
\subsection { One-electron reduced density matrix formulation}
%%%%%%%%%%%%%%%%
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For implementation purposes, we will use in the rest of this work
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(one-electron reduced) density matrices
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as basic variables, rather than Slater determinants.
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As the theory is applied later on to \textit { spin-polarized}
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systems, we drop spin indices in the density matrices, for convenience.
If we expand the
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ensemble KS orbitals (from which the determinants are constructed) in an atomic orbital (AO) basis,
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\beq
\MO { p} { } (\br { } ) = \sum _ { \mu } \cMO { \mu p} { } \AO { \mu } (\br { } ),
\eeq
\iffalse %%%%%%%%%%%%%%%%%%%%%%%%
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\titou { \beq
\SO { p} { } (\bx { } ) = s(\omega ) \sum _ { \mu } \cMO { \mu p} { } \AO { \mu } (\br { } ),
\eeq
where $ \bx { } = ( \omega , \br { } ) $ is a composite coordinate gathering spin and spatial degrees of freedom, and
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\beq
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s(\omega )
=
\begin { cases}
\alpha (\omega ), & \text { for spin-up electrons,} \\
\text { or} \\
\beta (\omega ), & \text { for spin-down electrons,}
\end { cases}
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\eeq
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}
\fi %%%%%%%%%%%%%%%%%%%%%
then the density matrix of the
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determinant $ \Det { ( K ) } $ can be expressed as follows in the AO basis:
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\beq
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\bGam { (K)} \equiv \eGam { \mu \nu } { (K)} = \sum _ { \SO { p} { } \in (K)} \cMO { \mu p} { } \cMO { \nu p} { } ,
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\eeq
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where the summation runs over the orbitals that are occupied in $ \Det { ( K ) } $ .
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The electron density of the $ K $ th KS determinant can then be evaluated
as follows:
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\beq
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\n { \bGam { (K)} } { } (\br { } ) = \sum _ { \mu \nu } \AO { \mu } (\br { } ) \eGam { \mu \nu } { (K)} \AO { \nu } (\br { } ),
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\eeq
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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% Manu's derivation %%%
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\iffalse %%
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\blue {
\beq
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n_ { \bmg ^ { (K)} } (\br { } )& =& \sum _ \sigma \left \langle \hat { \Psi } ^ \dagger (\br { } \sigma )\hat { \Psi } (\br { } \sigma )\right \rangle ^ { (K)}
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\nonumber \\
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& =& \sum _ \sigma \sum _ { pq} \varphi ^ \sigma _ p(\br { } )\varphi ^ \sigma _ q(\br { } )\left \langle \hat { a} _ { p^ \sigma ,\sigma } ^ \dagger \hat { a} _ { q^ \sigma ,\sigma } \right \rangle ^ { (K)}
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\nonumber \\
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& =& \sum _ \sigma \sum _ { \varphi ^ \sigma _ p\in (K)} \left (\varphi ^ \sigma _ p(\br { } )\right )^ 2
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\nonumber \\
& =& \sum _ \sigma \sum _ { \varphi ^ \sigma _ p\in (K)} \sum _ { \mu \nu } c^ \sigma _ { { \mu
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p} } c^ \sigma _ { { \nu p} } \AO { \mu } (\br { } )\AO { \nu } (\br { } )
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\nonumber \\
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& =& \sum _ { \mu \nu } \AO { \mu } (\br { } )\AO { \nu } (\br { } )\sum _ \sigma \sum _ { \varphi ^ \sigma _ p\in (K)} c^ \sigma _ { { \mu
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p} } c^ \sigma _ { { \nu p} }
\eeq
}
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\fi %%%
%%%% end Manu
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while the ensemble density matrix
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and the ensemble density read
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\beq
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\bGam { \bw }
= \sum _ { K\geq 0} \ew { K} \bGam { (K)}
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\equiv \eGam { \mu \nu } { \bw }
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= \sum _ { K\geq 0} \ew { K} \eGam { \mu \nu } { (K)} ,
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\eeq
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and
\beq
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\n { \bGam { \bw } } { } (\br { } ) = \sum _ { \mu \nu } \AO { \mu } (\br { } ) \eGam { \mu \nu } { \bw } \AO { \nu } (\br { } ),
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\eeq
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respectively.
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The exact individual energy expression in Eq.~\eqref { eq:exact_ ener_ level_ dets} can then be rewritten as
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\beq \label { eq:exact_ ind_ ener_ rdm}
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\begin { split}
\E { } { (I)}
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& =\Tr [\bGam{(I)} \bh]
+ \frac { 1} { 2} \Tr [\bGam{(I)} \bG \bGam{(I)}]
+ \E { c} { { \bw } } [\n { \bGam { \bw } } { } ]
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\\
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& + \int \fdv { \E { c} { \bw } [\n { \bGam { \bw } } { } ]} { \n { } { } (\br { } )}
\qty [ \n{\bGam{(I)}}{}(\br{}) - \n{\bGam{\bw}}{}(\br{}) ] d\br { }
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\\
& + \sum _ { K>0} \qty (\delta _ { IK} - \ew { K} )
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\left . \pdv { \E { c} { \bw } [\n { } { } ]} { \ew { K} } \right |_ { \n { } { } = \n { \bGam { \bw } } { } }
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,
\end { split}
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\eeq
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where
\beq
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\bh \equiv h_ { \mu \nu } = \mel * { \AO { \mu } } { \hh } { \AO { \nu } }
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\eeq
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denotes the matrix of the one-electron integrals.
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The exact individual Hx energies are obtained from the following trace formula
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\beq
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\Tr [\bGam{(K)} \bG \bGam{(L)}]
= \sum _ { \mu \nu \la \si } \eGam { \mu \nu } { (K)} \eG { \mu \nu \la \si } \eGam { \la \si } { (L)} ,
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\eeq
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where the antisymmetrized two-electron integrals read
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\beq
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\bG
\equiv G_ { \mu \nu \la \si }
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= \dbERI { \mu \nu } { \la \si }
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= \ERI { \mu \nu } { \la \si } - \ERI { \mu \si } { \la \nu } ,
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\eeq
with
\beq
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\ERI { \mu \nu } { \la \si } = \iint \frac { \AO { \mu } (\br { 1} ) \AO { \nu } (\br { 1} ) \AO { \la } (\br { 2} ) \AO { \si } (\br { 2} )} { \abs { \br { 1} - \br { 2} } } d\br { 1} d\br { 2} .
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\eeq
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%Note that, in Sec.~\ref{sec:results}, the theory is applied to (1D) spin
%polarized systems in which $\eGam{\mu\nu}{(K)\beta}=0$ and
%$G_{\mu\nu\lambda\omega}^{\alpha\alpha}\equiv G_{\mu\nu\lambda\omega}=({\mu}{\nu}\vert{\lambda}{\omega})
%-(\mu\omega\vert\lambda\nu)$.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%% Hx energy ...
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%%% Manu's derivation
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\iffalse %%%%
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\blue {
\beq
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& & \dfrac { 1} { 2} \sum _ { PQRS} \langle PQ\vert \vert
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RS\rangle \eGam { PR} ^ { (K)} \eGam { QS} ^ { (L)}
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\nonumber \\
& &
=\dfrac { 1} { 2} \sum _ { \sigma ,\tau } \sum _ { p^ { \sigma } q^ { \tau } RS}
\nonumber \\
& & \Big (\langle p^ \sigma \sigma q^ \tau \tau \vert RS\rangle -\langle
p^ \sigma \sigma q^ \tau \tau
\vert SR\rangle
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\Big )\Gamma ^ { (K)} _ { p^ \sigma \sigma ,R} \Gamma ^ { (L)} _ { q^ \tau \tau , S}
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\nonumber \\
& &
=\dfrac { 1} { 2} \sum _ { \sigma ,\tau } \sum _ { p^ { \sigma } q^ { \tau } }
\nonumber \\
& & \Big (\sum _ { r^ \sigma s^ \tau } \langle p^ \sigma q^ \tau \vert r^ \sigma s^ \tau \rangle
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\Gamma ^ { (K)\sigma } _ { p^ \sigma r^ \sigma } \Gamma ^ { (L)\tau } _ { q^ \tau s^ \tau }
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\nonumber \\
& & -\sum _ { s^ \sigma r^ \tau } \langle
p^ \sigma q^ \tau
\vert s^ \sigma r^ \tau \rangle
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\delta _ { \sigma \tau } \Gamma ^ { (K)\sigma } _ { p^ \sigma
r^ \sigma } \Gamma ^ { (L)\sigma } _ { q^ \sigma s^ \sigma } \Big )
\nonumber \\
& & =\dfrac { 1} { 2} \sum _ { \sigma ,\tau } \sum _ { p^ { \sigma } q^ { \tau } }
\nonumber \\
& & \left (\langle p^ \sigma q^ \tau \vert p^ \sigma q^ \tau \rangle
n_ { p^ \sigma } ^ { (K)\sigma } n_ { q^ \tau } ^ { (L)\tau }
-\delta _ { \sigma \tau } \langle p^ \sigma q^ \sigma \vert q^ \sigma p^ \sigma \rangle
n_ { p^ \sigma } ^ { (K)\sigma } n_ { q^ \sigma } ^ { (L)\sigma } \right )
\nonumber \\
& & =\dfrac { 1} { 2} \sum _ { \mu \nu \lambda \omega } \sum _ { \sigma ,\tau } \Big (\langle { \mu } { \lambda } \vert { \nu } { \omega } \rangle
\Gamma _ { \mu \nu } ^ { (K)\sigma } \Gamma _ { \lambda \omega } ^ { (L)\tau }
-\delta _ { \sigma \tau } \langle \mu \lambda \vert \omega \nu \rangle \Gamma _ { \mu \nu } ^ { (K)\sigma } \Gamma _ { \lambda \omega } ^ { (L)\sigma }
\Big )
\nonumber \\
& & =\dfrac { 1} { 2} \sum _ { \mu \nu \lambda \omega } \sum _ { \sigma ,\tau } \Big (\langle { \mu } { \lambda } \vert { \nu } { \omega } \rangle
-\delta _ { \sigma \tau } \langle \mu \lambda \vert \omega \nu \rangle
\Big )
\Gamma _ { \mu \nu } ^ { (K)\sigma } \Gamma _ { \lambda \omega } ^ { (L)\tau }
\nonumber \\
& & =\dfrac { 1} { 2} \sum _ { \mu \nu \lambda \omega } \sum _ { \sigma ,\tau } \Big [({ \mu } { \nu } \vert { \lambda } { \omega } )
-\delta _ { \sigma \tau } (\mu \omega \vert \lambda \nu )
\Big ]
\Gamma _ { \mu \nu } ^ { (K)\sigma } \Gamma _ { \lambda \omega } ^ { (L)\tau }
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\eeq
}
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\fi %%%%%%%
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%%%%
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%%%%%%%%%%%%%%%%%%%%%
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\iffalse %%%% Manu's derivation ...
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\blue {
\beq
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n^ { \bw } ({ \br { } } )& =& \sum _ { K\geq 0} \sum _ { \sigma =\alpha ,\beta } { \tt
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w} _ Kn^ { (K)} ({ \bfx } )
\nonumber \\
& =&
\sum _ { K\geq 0} \sum _ { \sigma =\alpha ,\beta } { \tt
w} _ K\sum _ { pq} \varphi _ p({ \bfx } )\varphi _ q({ \bfx } )\Gamma _ { pq} ^ { (K)}
\nonumber \\
& =&
\sum _ { \sigma =\alpha ,\beta }
\sum _ { K\geq 0}
{ \tt
w} _ K\sum _ { p\in (K)} \varphi ^ 2_ p({ \bfx } )
\nonumber \\
& =&
\sum _ { \sigma =\alpha ,\beta }
\sum _ { K\geq 0}
{ \tt
w} _ K
\sum _ { \mu \nu }
\sum _ { p\in (K)} c_ { \mu p} c_ { \nu p} \AO { \mu } ({ \bfx } )\AO { \nu } ({ \bfx } )
\nonumber \\
& =& \sum _ { \sigma =\alpha ,\beta } \sum _ { \mu \nu } \AO { \mu } ({ \bfx } )\AO { \nu } ({ \bfx } ){ \Gamma } ^ { \bw } _ { \mu \nu }
\eeq
}
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\fi %%%%%%%% end
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%%%%%%%%%%%%%%%
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%\subsection{Hybrid GOK-DFT}
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%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%
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\subsection { Approximations} \label { subsec:approx}
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%%%%%%%%%%%%%%%
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In the following, GOK-DFT will be applied
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to 1D
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spin-polarized systems where
Hartree and exchange energies cannot be separated.
For that reason, we will substitute the Hartree--Fock (HF) density-matrix-functional interaction energy,
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\beq \label { eq:eHF-dens_ mat_ func}
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\WHF [\bGam{}] = \frac { 1} { 2} \Tr [\bGam{} \bG \bGam{}] ,
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\eeq
for the Hx density-functional energy in the variational energy
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expression of Eq.~\eqref { eq:var_ ener_ gokdft} , thus leading to the
following approximation:
\beq \label { eq:min_ with_ HF_ ener_ fun}
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\bGam { \bw }
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\rightarrow \argmin _ { \bgam { \bw } }
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\qty {
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\Tr [\bgam{\bw} \bh ] + \WHF [ \bgam{\bw}] + \E { c} { \bw } [\n { \bgam { \bw } } { } ]
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} .
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\eeq
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The minimizing ensemble density matrix in Eq.~\eqref { eq:min_ with_ HF_ ener_ fun} fulfills the following
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stationarity condition
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\beq \label { eq:commut_ F_ AO}
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\bF { \bw } \bGam { \bw } \bS = \bS \bGam { \bw } \bF { \bw } ,
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\eeq
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where $ \bS \equiv \eS { \mu \nu } = \braket * { \AO { \mu } } { \AO { \nu } } $ is the
overlap matrix and the ensemble Fock-like matrix reads
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\beq
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\bF { \bw } \equiv \eF { \mu \nu } { \bw } = \eh { \mu \nu } { \bw } +
\sum _ { \la \si } \eG { \mu \nu \la \si } \eGam { \la \si } { \bw } ,
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\eeq
with
\beq
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\eh { \mu \nu } { \bw }
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= \eh { \mu \nu } { } + \int \AO { \mu } (\br { } ) \fdv { \E { c} { \bw } [\n { \bGam { \bw } } { } ]} { \n { } { } (\br { } )} \AO { \nu } (\br { } ) d\br { } .
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\eeq
%%%%%%%%%%%%%%%
\iffalse %%%%%%
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% Manu's derivation %%%%
\color { blue}
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I am teaching myself ...\\
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Stationarity condition
\beq
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& & 0=\sum _ { K\geq 0} w_ K\sum _ { t^ \sigma } \Big (f_ { p^ \sigma \sigma ,t^ \sigma \sigma } \Gamma ^ { (K)\sigma } _ { t^ \sigma
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q^ \sigma } -\Gamma ^ { (K)\sigma } _ { p^ \sigma
t^ \sigma } f_ { t^ \sigma \sigma ,q^ \sigma \sigma } \Big )
\nonumber \\
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& & =\sum _ { K\geq 0} w_ K
\Big (f_ { p^ \sigma \sigma ,q^ \sigma \sigma } n^ { (K)\sigma } _ { q^ \sigma } -n^ { (K)\sigma } _ { p^ \sigma } f_ { p^ \sigma \sigma ,q^ \sigma \sigma } \Big )
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\nonumber \\
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& &
=\sum _ { \mu \nu } \sum _ { K\geq 0} w_ KF_ { \mu \nu } ^ \sigma c^ \sigma _ { \mu
p} c^ \sigma _ { \nu q} \left (n^ { (K)\sigma } _ { q^ \sigma } -n^ { (K)\sigma } _ { p^ \sigma } \right )
\eeq
thus leading to
\beq
& & 0=\sum _ { p^ \sigma q^ \sigma } c^ \sigma _ { \lambda
p} c^ \sigma _ { \omega q} \left (\sum _ { \mu \nu } \sum _ { K\geq 0} w_ KF_ { \mu \nu } ^ \sigma c^ \sigma _ { \mu
p} c^ \sigma _ { \nu q} \left (n^ { (K)\sigma } _ { q^ \sigma } -n^ { (K)\sigma } _ { p^ \sigma } \right )\right )
\nonumber \\
& & =\sum _ { \mu \nu } \sum _ { K\geq 0} w_ K
F_ { \mu \nu } ^ \sigma \left (\Gamma ^ { (K)\sigma } _ { \nu \omega } \sum _ { p^ \sigma } c^ \sigma _ { \lambda
p} c^ \sigma _ { \mu
p} -\Gamma ^ { (K)\sigma } _ { \mu \lambda } \sum _ { q^ \sigma } c^ \sigma _ { \omega q} c^ \sigma _ { \nu q} \right )
\nonumber \\
\eeq
If we denote $ M ^ \sigma _ { \lambda \mu } = \sum _ { p ^ \sigma } c ^ \sigma _ { \lambda
p} c^ \sigma _ { \mu
p} $ it comes
\beq
S_ { \mu \nu } =\sum _ { \lambda \omega } S_ { \mu \lambda } M^ \sigma _ { \lambda \omega } S_ { \omega \nu }
\eeq
which simply means that
\beq
{ \bm S} ={ \bm S} { \bm M} { \bm S}
\eeq
or, equivalently,
\beq
{ \bm M} ={ \bm S} ^ { -1} .
\eeq
The stationarity condition simply reads
\beq
\sum _ { \mu \nu } F_ { \mu \nu } ^ \sigma \left (\Gamma ^ { \bw \sigma } _ { \nu \omega }
\left [{\bm S}^{-1}\right] _ { \lambda \mu }
-\Gamma ^ { \bw \sigma } _ { \mu \lambda } \left [{\bm S}^{-1}\right] _ { \omega \nu } \right )
=0
\eeq
thus leading to
\beq
{ \bm S} ^ { -1} { { \bm F} ^ \sigma } { \bm \Gamma } ^ { \bw \sigma } ={ \bm \Gamma } ^ { \bw \sigma } { { \bm F} ^ \sigma } { \bm S} ^ { -1}
\eeq
or, equivalently,
\beq
{ { \bm F} ^ \sigma } { \bm \Gamma } ^ { \bw \sigma } { \bm S} ={ \bm S} { \bm
\Gamma } ^ { \bw \sigma } { { \bm F} ^ \sigma } .
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\eeq
%%%%%
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Fock operator:\\
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\beq
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& & f_ { p^ \sigma \sigma ,q^ \sigma \sigma } -\langle \varphi _ p^ \sigma \vert \hat { h} \vert \varphi _ q^ \sigma \rangle
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\nonumber \\
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& & =\sum _ { L\geq 0} w_ L\sum _ { \tau } \sum _ { r^ \tau s^ \tau }
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\nonumber \\
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& &
\Big (\langle p^ \sigma r^ \tau \vert
q^ \sigma s^ \tau \rangle
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-\delta _ { \sigma \tau } \langle p^ \sigma r^ \sigma \vert
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s^ \sigma q^ \sigma \rangle
\Big )
\Gamma ^ { (L)\tau } _ { r^ \tau
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s^ \tau }
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\nonumber \\
& &
=\sum _ { L\geq 0} w_ L\sum _ { \tau } \sum _ { r^ \tau } \Big (\langle p^ \sigma r^ \tau \vert
q^ \sigma r^ \tau \rangle
-\delta _ { \sigma \tau } \langle p^ \sigma r^ \tau \vert
r^ \tau q^ \sigma \rangle
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\Big )
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n^ { (L)\tau } _ { r^ \tau }
\nonumber \\
& & =\sum _ { L\geq 0} w_ L
\sum _ { \lambda \omega } \sum _ { \tau } \Big [\langle
p^ \sigma \lambda \vert q^ \sigma \omega \rangle
-\delta _ { \sigma \tau }
\langle
p^ \sigma \lambda \vert \omega q^ \sigma \rangle \Big ]
\Gamma ^ { (L)\tau } _ { \lambda \omega }
\nonumber \\
& & =
\sum _ { \lambda \omega } \sum _ { \tau } \Big [\langle
p^ \sigma \lambda \vert q^ \sigma \omega \rangle
-\delta _ { \sigma \tau }
\langle
p^ \sigma \lambda \vert \omega q^ \sigma \rangle \Big ]
\Gamma ^ { \bw \tau } _ { \lambda \omega }
\nonumber \\
& & =\sum _ { \mu \nu \lambda \omega } \sum _ { \tau }
\Big (\langle { \mu } { \lambda } \vert { \nu } { \omega } \rangle
-\delta _ { \sigma \tau } \langle \mu \lambda \vert \omega \nu \rangle
\Big )\Gamma ^ { \bw \tau } _ { \lambda \omega } c^ \sigma _ { \mu p} c^ \sigma _ { \nu q}
\nonumber \\
\eeq
or, equivalently,
\beq
f_ { p^ \sigma \sigma ,q^ \sigma \sigma } =\sum _ { \mu \nu } F_ { \mu \nu } ^ \sigma c^ \sigma _ { \mu p} c^ \sigma _ { \nu q}
\eeq
where
\beq
F_ { \mu \nu } ^ \sigma =h_ { \mu \nu } +\sum _ { \lambda \omega } \sum _ \tau
G_ { \mu \nu \lambda \omega } ^ { \sigma \tau } \Gamma ^ { \bw \tau } _ { \lambda \omega }
\eeq
and
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\color { black}
\\
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\fi %%%%%%%%%%%
%%%%% end Manu
%%%%%%%%%%%%%%%%%%%%
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Note that, within the approximation of Eq.~\eqref { eq:min_ with_ HF_ ener_ fun} , the ensemble density matrix is
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optimized with a non-local exchange potential rather than a
density-functional local one, as expected from
Eq.~\eqref { eq:var_ ener_ gokdft} . This procedure is actually general, \ie ,
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applicable to not-necessarily spin-polarized and real (higher-dimensional) systems.
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As readily seen from Eq.~\eqref { eq:eHF-dens_ mat_ func} , inserting the
ensemble density matrix into the HF interaction energy functional
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introduces unphysical \textit { ghost-interaction} errors \cite { Gidopoulos_ 2002, Pastorczak_ 2014, Alam_ 2016, Alam_ 2017, Gould_ 2017}
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as well as \textit { curvature} :\cite { Alam_ 2016,Alam_ 2017}
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\beq \label { eq:WHF}
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\begin { split}
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\WHF [\bGam{\bw}]
& = \frac { 1} { 2} \sum _ { K\geq 0} \ew { K} ^ 2 \Tr [\bGam{(K)} \bG \bGam{(K)}]
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\\
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& + \sum _ { L>K\geq 0} \ew { K} \ew { L} \Tr [\bGam{(K)} \bG \bGam{(L)}] .
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\end { split}
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\eeq
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The ensemble energy is of course expected to vary linearly with the ensemble
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weights [see Eq.~\eqref { eq:exact_ GOK_ ens_ ener} ].
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The explicit linear weight dependence of the ensemble Hx energy is actually restored when evaluating the individual energy
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levels on the basis of Eq.~\eqref { eq:exact_ ind_ ener_ rdm} .
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Turning to the density-functional ensemble correlation energy, the
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following ensemble local-density approximation (eLDA) will be employed
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\beq \label { eq:eLDA_ corr_ fun}
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\E { c} { \bw } [\n { } { } ]\approx \int \n { } { } (\br { } ) \e { c} { \bw } (\n { } { } (\br { } )) d\br { } ,
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\eeq
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where the ensemble correlation energy per particle
\beq \label { eq:decomp_ ens_ correner_ per_ part}
\e { c} { \bw } (\n { } { } )=\sum _ { K\geq 0} w_ K\be { c} { (K)} (\n { } { } )
\eeq
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is explicitly \textit { weight dependent} .
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As shown in Sec.~\ref { sec:eDFA} , the latter can be constructed
from a finite uniform electron gas model.
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%\titou{Manu, I think we should clearly define here what the expression of the ensemble energy with and without GOC.
%What do you think?}
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The resulting KS-eLDA ensemble energy obtained via Eq.~\eqref { eq:min_ with_ HF_ ener_ fun}
reads
\beq \label { eq:Ew-GIC-eLDA}
\E { eLDA} { \bw } =\Tr [\bGam{\bw}\bh] + \WHF [\bGam{\bw}] +\int
\e { c} { \bw } (\n { \bGam { \bw } } { } (\br { } )) \n { \bGam { \bw } } { } (\br { } ) d\br { } .
\eeq
%Manu, would it be useful to add this equation and the corresponding text?
%I think it is useful for the discussion later on when we talk about the different contributions to the excitation energies.
%This shows clearly that there is a correction due to the correlation functional itself as well as a correction due to the ensemble correlation derivative
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Combining Eq.~\eqref { eq:exact_ ind_ ener_ rdm} with
Eq.~\eqref { eq:eLDA_ corr_ fun} leads to our final expression of the
KS-eLDA energy levels
\beq \label { eq:EI-eLDA}
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\begin { split}
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\E { { eLDA} } { (I)}
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=
\E { HF} { (I)}
+ \Xi _ \text { c} ^ { (I)}
+ \Upsilon _ \text { c} ^ { (I)} ,
\end { split}
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\eeq
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where
\beq \label { eq:ind_ HF-like_ ener}
\E { HF} { (I)} =\Tr [\bGam{(I)} \bh] + \frac { 1} { 2} \Tr [\bGam{(I)} \bG \bGam{(I)}]
\eeq
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is the analog for ground and excited states (within an ensemble) of the HF energy, and
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\begin { gather}
\begin { split}
\Xi _ \text { c} ^ { (I)}
& = \int \e { c} { \bw } (\n { \bGam { \bw } } { } (\br { } )) \n { \bGam { (I)} } { } (\br { } ) d\br { }
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\\
&
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+ \int \n { \bGam { \bw } } { } (\br { } ) \qty [ \n{\bGam{(I)}}{}(\br{}) - \n{\bGam{\bw}}{}(\br{}) ]
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\left . \pdv { \e { c} { { \bw } } (\n { } { } )} { \n { } { } } \right |_ { \n { } { } =
\n { \bGam { \bw } } { } (\br { } )} d\br { } ,
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\\
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\end { split}
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\\
\Upsilon _ \text { c} ^ { (I)}
= \int \sum _ { K>0} \qty (\delta _ { IK} - \ew { K} ) \n { \bGam { \bw } } { } (\br { } )
\left . \pdv { \e { c} { \bw } (\n { } { } )} { \ew { K} } \right |_ { \n { } { } =\n { \bGam { \bw } } { } (\br { } )} d\br { } .
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\end { gather}
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If, for analysis purposes, we Taylor expand the density-functional
correlation contributions
around the $ I $ th KS state density
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$ \n { \bGam { ( I ) } } { } ( \br { } ) $ , the
second term on the right-hand side
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of Eq.~\eqref { eq:EI-eLDA} can be simplified as follows through first order in
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$ \n { \bGam { \bw } } { } ( \br { } ) - \n { \bGam { ( I ) } } { } ( \br { } ) $ :
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\beq \label { eq:Taylor_ exp_ ind_ corr_ ener_ eLDA}
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\Xi _ \text { c} ^ { (I)}
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= \int \e { c} { \bw } (\n { \bGam { (I)} } { } (\br { } )) \n { \bGam { (I)} } { } (\br { } ) d\br { }
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+ \order { [\n { \bGam { \bw } } { } (\br { } )-\n { \bGam { (I)} } { } (\br { } )]^ 2} .
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\eeq
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Therefore, it can be identified as
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an individual-density-functional correlation energy where the density-functional
correlation energy per particle is approximated by the ensemble one for
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all the states within the ensemble.
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Let us stress that, to the best of our knowledge, eLDA is the first
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density-functional approximation that incorporates ensemble weight
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dependencies explicitly, thus allowing for the description of derivative
discontinuities [see Eq.~\eqref { eq:excited_ ener_ level_ gs_ lim} and the
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comment that follows] { \it via} the third term on the right-hand side
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of Eq.~\eqref { eq:EI-eLDA} . According to the decomposition of
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the ensemble
correlation energy per particle in Eq.
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\eqref { eq:decomp_ ens_ correner_ per_ part} , the latter can be recast
\begin { equation}
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\Upsilon _ \text { c} ^ { (I)}
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%&=
%\int \sum_{K>0} \qty(\delta_{IK} - \ew{K} ) \n{\bGam{\bw}}{}(\br{})
%\Big(\be{c}{(K)}(\n{\bGam{\bw}}{}(\br{}))
%-
%\be{c}{(0)}(\n{\bGam{\bw}}{}(\br{}))
%\Big)
%d\br{}
%\\
=\int
\qty [\be { c} { (I)} (\n { \bGam { \bw } } { } (\br { } ))
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-
\e { c} { \bw } (\n { \bGam { \bw } } { } (\br { } ))
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] \n { \bGam { \bw } } { } (\br { } )
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d\br { } ,
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%\sum_{K>0}\delta_{IK}\left. \pdv{\e{c}{\bw}(\n{}{})}{\ew{K}} \right|_{\n{}{}=\n{\bGam{\bw}}{}(\br{})}
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\end { equation}
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thus leading to the following Taylor expansion through first order in
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$ \n { \bGam { \bw } } { } ( \br { } ) - \n { \bGam { ( I ) } } { } ( \br { } ) $ :
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\beq \label { eq:Taylor_ exp_ DDisc_ term}
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\begin { split}
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\Upsilon _ \text { c} ^ { (I)}
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%& = \int \sum_{K>0} \qty(\delta_{IK} - \ew{K} ) \n{\bGam{\bw}}{}(\br{})
% \left. \pdv{\e{c}{\bw}(\n{}{})}{\ew{K}} \right|_{\n{}{}=\n{\bGam{\bw}}{}(\br{})} d\br{}
%\\
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& =
\int \qty [ \be{c}{(I)}(\n{\bGam{(I)}}{}(\br{})) - \e{c}{\bw}(\n{\bGam{(I)}}{}(\br{})) ] \n { \bGam { (I)} } { } (\br { } ) d\br { }
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\\
& +\int \Bigg [
\n { \bGam { (I)} } { } (\br { } )
\left .\left (
\pdv { \be { c} { { (I)} } (\n { } { } )} { \n { } { } }
-
\pdv { \e { c} { { \bw } } (\n { } { } )} { \n { } { } }
\right )\right |_ { \n { } { } =
\n { \bGam { (I)} } { } (\br { } )}
\\
& +\be { c} { (I)} (\n { \bGam { (I)} } { } (\br { } ))
-
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\e { c} { \bw } (\n { \bGam { (I)} } { } (\br { } ))\Bigg ]
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\qty [\n{\bGam{\bw}}{}(\br{})-\n{\bGam{(I)}}{}(\br{})]
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d\br { }
\\
&
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+ \order { [\n { \bGam { \bw } } { } (\br { } )-\n { \bGam { (I)} } { } (\br { } )]^ 2} .
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\end { split}
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\eeq
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As readily seen from Eqs. \eqref { eq:Taylor_ exp_ ind_ corr_ ener_ eLDA} and \eqref { eq:Taylor_ exp_ DDisc_ term} , the
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role of the correlation ensemble derivative contribution $ \Upsilon _ \text { c } ^ { ( I ) } $ is, through zeroth order, to substitute the expected
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individual correlation energy per particle for the ensemble one.
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Let us finally mention that, while the weighted sum of the
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individual KS-eLDA energy levels delivers a \textit { ghost-interaction-corrected} (GIC) version of
the KS-eLDA ensemble energy, \ie ,
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\beq \label { eq:Ew-eLDA}
\begin { split}
\E { GIC-eLDA} { \bw } & =\sum _ { I\geq 0} \ew { I} \E { { eLDA} } { (I)}
\\
& =
\E { eLDA} { \bw }
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-\WHF [\bGam{\bw}] +\sum _ { I\geq 0} \ew { I} \WHF [ \bGam{(I)}] ,
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\end { split}
\eeq
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the excitation energies computed from the KS-eLDA individual energy level
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expressions in Eq. \eqref { eq:EI-eLDA} can be simplified as follows:
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\beq \label { eq:Om-eLDA}
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\begin { split}
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\Ex { eLDA} { (I)}
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& =
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\Ex { HF} { (I)}
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\\
& + \int
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\qty [\e{c}{{\bw}}(\n{}{})+n\pdv{\e{c}{{\bw}}(\n{}{})}{\n{}{}}]
_ { \n { } { } =
\n { \bGam { \bw } } { } (\br { } )}
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\qty [ \n{\bGam{(I)}}{}(\br{}) - \n{\bGam{(0)}}{}(\br{}) ] d\br { }
\\ & + \DD { c} { (I)} ,
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\end { split}
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\eeq
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where the HF-like excitation energies, $ \Ex { HF } { ( I ) } = \E { HF } { ( I ) } -
\E { HF} { (0)} $ , are determined from a single set of ensemble KS orbitals and
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\beq \label { eq:DD-eLDA}
\DD { c} { (I)}
= \int \n { \bGam { \bw } } { } (\br { } )
\left . \pdv { \e { c} { \bw } (\n { } { } )} { \ew { I} } \right |_ { \n { } { } =\n { \bGam { \bw } } { } (\br { } )} d\br { }
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\eeq
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is the eLDA correlation ensemble derivative contribution to the $ I $ th excitation energy.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\section { Density-functional approximations for ensembles}
\label { sec:eDFA}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\subsection { Paradigm}
\label { sec:paradigm}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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Most of the standard local and semi-local density-functional approximations rely on the infinite uniform electron gas model (also known as jellium). \cite { ParrBook, Loos_ 2016}
One major drawback of the jellium paradigm, when it comes to develop density-functional approximations for ensembles, is that the ground and excited states are not easily accessible like in a molecule. \cite { Gill_ 2012, Loos_ 2012, Loos_ 2014a, Loos_ 2014b, Agboola_ 2015, Loos_ 2017a}
Moreover, because the infinite uniform electron gas model is a metal, it is gapless, which means that both the fundamental and optical gaps are zero.
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From this point of view, using finite uniform electron gases, \cite { Loos_ 2011b,
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Gill_ 2012} which have, like an atom, discrete energy levels and non-zero
gaps, can be seen as more relevant in this context. \cite { Loos_ 2014a, Loos_ 2014b, Loos_ 2017a}
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However, an obvious drawback of using finite uniform electron gases is
that the resulting density-functional approximation for ensembles
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will inexorably depend on the number of electrons in the finite uniform electron gas (see below).
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Here, we propose to construct a weight-dependent LDA functional for the
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calculation of excited states in 1D systems by combining finite uniform electron gases with the
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usual infinite uniform electron gas paradigm.
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As a finite uniform electron gas, we consider the ringium model in which electrons move on a perfect ring (\ie , a circle) but interact \textit { through} the ring. \cite { Loos_ 2012, Loos_ 2013a, Loos_ 2014b}
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The most appealing feature of ringium regarding the development of
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functionals in the context of GOK-DFT is the fact that both ground- and
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excited-state densities are uniform, and therefore { \it equal} .
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As a result, the ensemble density will remain constant (and uniform) as the ensemble weights vary.
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This is a necessary condition for being able to model the
correlation ensemble derivatives [last term
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on the right-hand side of Eq.~\eqref { eq:exact_ ener_ level_ dets} ].
Moreover, it has been shown that, in the thermodynamic limit, the ringium model is equivalent to the ubiquitous infinite uniform electron gas paradigm. \cite { Loos_ 2013,Loos_ 2013a}
Let us stress that, in a finite uniform electron gas like ringium, the interacting and
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noninteracting densities match individually for all the states within the
ensemble
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(these densities are all equal to the uniform density), which means that
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so-called density-driven correlation
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effects~\cite { Gould_ 2019,Gould_ 2019_ insights,Senjean_ 2020,Fromager_ 2020} are absent from the model.
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Here, we will consider the most simple ringium system featuring electronic correlation effects, \ie , the two-electron ringium model.
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The present weight-dependent density-functional approximation is specifically designed for the
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calculation of excited-state energies within GOK-DFT.
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To take into account both single and double excitations simultaneously, we consider a three-state ensemble including:
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(i) the ground state ($ I = 0 $ ), (ii) the first singly-excited state ($ I = 1 $ ), and (iii) the first doubly-excited state ($ I = 2 $ ) of the (spin-polarized) two-electron ringium system.
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To ensure the GOK variational principle, \cite { Gross_ 1988a} the
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triensemble weights must fulfil the following conditions: \cite { Deur_ 2019}
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$ 0 \le \ew { 2 } \le 1 / 3 $ and $ \ew { 2 } \le \ew { 1 } \le ( 1 - \ew { 2 } ) / 2 $ , where $ \ew { 1 } $ and $ \ew { 2 } $ are the weights associated with the singly- and doubly-excited states, respectively.
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All these states have the same (uniform) density $ \n { } { } = 2 / ( 2 \pi R ) $ , where $ R $ is the radius of the ring on which the electrons are confined.
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We refer the interested reader to Refs.~\onlinecite { Loos_ 2012, Loos_ 2013a, Loos_ 2014b} for more details about this paradigm.
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Generalization to a larger number of states is straightforward and is left for future work.
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%The constraint in \titou{red} is wrong. If $\ew{2}=0$, you should be allowed
%to consider an equi-bi-ensemble
%for which $\ew{1}=1/2$. This possibility is excluded with your
%inequalities. The correct constraints are given in Ref.~\cite{Deur_2019}
%and are the ones you also mentioned, \ie, $0 \le \ew{2} \le 1/3$ and
%$\ew{2} \le \ew{1} \le (1-\ew{2})/2$.}
%\manu{
%Just in case, starting from
%\beq
%\begin{split}
%0\leq \ew{2}\leq \ew{1}\leq (1-\ew{1}-\ew{2})
%\\
%\end{split}
%\eeq
%we obtain
%\beq
%0\leq \ew{2}\leq \ew{1}\leq (1-\ew{2})/2
%\eeq
%which implies $\ew{2}\leq(1-\ew{2})/2$ or, equivalently, $\ew{2}\leq
%1/3$.
%}
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%%% TABLE 1 %%%
\begin { table*}
\caption {
\label { tab:OG_ func}
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Parameters of the weight-dependent correlation density-functional approximations defined in Eq.~\eqref { eq:ec} .}
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% \begin{ruledtabular}
\begin { tabular} { lcddd}
\hline \hline
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State & $ I $ & \tabc { $ a _ 1 ^ { ( I ) } $ } & \tabc { $ a _ 2 ^ { ( I ) } $ } & \tabc { $ a _ 3 ^ { ( I ) } $ } \\
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\hline
Ground state & $ 0 $ & -0.0137078 & 0.0538982 & 0.0751740 \\
Singly-excited state & $ 1 $ & -0.0238184 & 0.00413142 & 0.0568648 \\
Doubly-excited state & $ 2 $ & -0.00935749 & -0.0261936 & 0.0336645 \\
\hline \hline
\end { tabular}
% \end{ruledtabular}
\end { table*}
%%% %%% %%% %%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\subsection { Weight-dependent correlation functional}
\label { sec:Ec}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
Based on highly-accurate calculations (see { \SI } for additional details), one can write down, for each state, an accurate analytical expression of the reduced (\ie , per electron) correlation energy \cite { Loos_ 2013a, Loos_ 2014a} via the following Pad\' e approximant
\begin { equation}
\label { eq:ec}
\e { c} { (I)} (\n { } { } ) = \frac { a_ 1^ { (I)} \, \n { } { } } { \n { } { } + a_ 2^ { (I)} \sqrt { \n { } { } } + a_ 3^ { (I)} } ,
\end { equation}
where the $ a _ k ^ { ( I ) } $ 's are state-specific fitting parameters provided in Table \ref { tab:OG_ func} .
The value of $ a _ 1 ^ { ( I ) } $ is obtained via the exact high-density expansion of the correlation energy. \cite { Loos_ 2013a, Loos_ 2014a}
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Equation \eqref { eq:ec} provides three state-specific correlation density-functional approximations based on a two-electron system.
Combining these, one can build the following three-state weight-dependent correlation density-functional approximation:
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\begin { equation}
\label { eq:ecw}
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%\e{c}{\bw}(\n{}{})
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\Tilde { \epsilon } _ { \rm c} ^ \bw (n)= (1-\ew { 1} -\ew { 2} ) \e { c} { (0)} (\n { } { } ) + \ew { 1} \e { c} { (1)} (\n { } { } ) + \ew { 2} \e { c} { (2)} (\n { } { } ).
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\end { equation}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\subsection { LDA-centered functional}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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One of the main driving force behind the popularity of DFT is its ``universal'' nature, as xc density functionals can be applied to any electronic system.
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Obviously, the two-electron-based density-functional approximation for ensemble defined in Eq.~\eqref { eq:ecw} does not have this feature as it does depend on the number of electrons constituting the finite uniform electron gas.
However, one can partially cure this dependency by applying a simple embedding scheme in which the two-electron finite uniform electron gas (the impurity) is embedded in the infinite uniform electron gas (the bath).
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The weight-dependence of the correlation functional is then carried exclusively by the impurity [\ie , the functional defined in Eq.~\eqref { eq:ecw} ], while the remaining correlation effects are provided by the bath (\ie , the usual LDA correlation functional).
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Following this simple strategy, which can be further theoretically justified by the generalized adiabatic connection formalism for ensembles (GACE) originally derived by Franck and Fromager, \cite { Franck_ 2014} we propose to \emph { shift} the two-electron-based density-functional approximation for ensemble defined in Eq.~\eqref { eq:ecw} as follows:
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\begin { equation}
\label { eq:becw}
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\Tilde { \epsilon } _ { \rm c} ^ \bw (n)\rightarrow { \e { c} { \bw } (\n { } { } )} = (1-\ew { 1} -\ew { 2} ) \be { c} { (0)} (\n { } { } ) + \ew { 1} \be { c} { (1)} (\n { } { } ) + \ew { 2} \be { c} { (2)} (\n { } { } ),
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\end { equation}
where
\begin { equation}
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\be { c} { (I)} (\n { } { } ) = \e { c} { (I)} (\n { } { } ) + \e { c} { \text { LDA} } (\n { } { } ) - \e { c} { (0)} (\n { } { } ).
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\end { equation}
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In the following, we will use the LDA correlation functional that has been specifically designed for 1D systems in
Ref.~\onlinecite { Loos_ 2013} :
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\begin { equation}
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\label { eq:LDA}
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\e { c} { \text { LDA} } (\n { } { } )
= a_ 1^ \text { LDA} F\qty [1,\frac{3}{2},a_3^\text{LDA}, \frac{a_1^\text{LDA}(1-a_3^\text{LDA})}{a_2^\text{LDA}} {\n{}{}}^{-1}] ,
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\end { equation}
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where $ F ( a,b,c,x ) $ is the Gauss hypergeometric function, \cite { NISTbook} and
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\begin { subequations}
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\begin { align}
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a_ 1^ \text { LDA} & = - \frac { \pi ^ 2} { 360} ,
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\\
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a_ 2^ \text { LDA} & = \frac { 3} { 4} - \frac { \ln { 2\pi } } { 2} ,
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\\
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a_ 3^ \text { LDA} & = 2.408779.
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\end { align}
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\end { subequations}
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Note that the strategy described in Eq.~\eqref { eq:becw} is general and
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can be applied to real (higher-dimensional) systems. In order to make the
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connection with the GACE formalism \cite { Franck_ 2014,Deur_ 2017} more explicit, one may
recast Eq.~\eqref { eq:becw} as
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\begin { equation}
\label { eq:eLDA}
\begin { split}
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{ \e { c} { \bw } (\n { } { } )}
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& = \e { c} { \text { LDA} } (\n { } { } )
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\\
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& + \ew { 1} \qty [\e{c}{(1)}(\n{}{})-\e{c}{(0)}(\n{}{})] + \ew { 2} \qty [\e{c}{(2)}(\n{}{})-\e{c}{(0)}(\n{}{})] ,
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\end { split}
\end { equation}
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or, equivalently,
\begin { equation}
\label { eq:eLDA_ gace}
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{ \e { c} { \bw } (\n { } { } )}
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= \e { c} { \text { LDA} } (\n { } { } )
+ \sum _ { K>0} \int _ 0^ { \ew { K} }
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\qty [\e{c}{(K)}(\n{}{})-\e{c}{(0)}(\n{}{})] d\xi _ K,
\end { equation}
where the $ K $ th correlation excitation energy (per electron) is integrated over the
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ensemble weight $ \xi _ K $ at fixed (uniform) density $ \n { } { } $ .
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Equation \eqref { eq:eLDA_ gace} nicely highlights the centrality of the
LDA in the present density-functional approximation for ensembles.
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In particular, $ { \e { c } { ( 0 , 0 ) } ( \n { } { } ) } = \e { c } { \text { LDA } } ( \n { } { } ) $ .
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Consequently, in the following, we name this correlation functional ``eLDA'' as it is a natural extension of the LDA for ensembles.
Finally, we note that, by construction,
\begin { equation}
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{ \pdv { \e { c} { \bw } (\n { } { } )} { \ew { J} } = \e { c} { (J)} (\n { } { } ) - \e { c} { (0)} (\n { } { } ).}
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\end { equation}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section { Computational details}
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\label { sec:comp_ details}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
Having defined the eLDA functional in the previous section [see Eq.~\eqref { eq:eLDA} ], we now turn to its validation.
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Our testing playground for the validation of the eLDA functional is the ubiquitous ``electrons in a box'' model where $ \nEl $ electrons are confined in a 1D box of length $ L $ , a family of systems that we call $ \nEl $ -boxium in the following.
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In particular, we investigate systems where $ L $ ranges from $ \pi / 8 $ to $ 8 \pi $ and $ 2 \le \nEl \le 7 $ .
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These inhomogeneous systems have non-trivial electronic structure properties which can be tuned by varying the box length.
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For small $ L $ , the system is weakly correlated, while strong correlation effects dominate in the large-$ L $ regime. \cite { Rogers_ 2017,Rogers_ 2016}
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We use as basis functions the (orthonormal) orbitals of the one-electron system, \ie ,
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\begin { equation}
\AO { \mu } (x) =
\begin { cases}
\sqrt { 2/L} \cos (\mu \pi x/L), & \mu \text { is odd,}
\\
\sqrt { 2/L} \sin (\mu \pi x/L), & \mu \text { is even,}
\end { cases}
\end { equation}
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with $ \mu = 1 , \ldots , \nBas $ and $ \nBas = 30 $ for all calculations.
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The convergence threshold $ \tau = \max { \abs { \bF { \bw } \bGam { \bw }
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\bS - \bS \bGam { \bw } \bF { \bw } } } $ [ see Eq.~ \eqref { eq:commut _ F _ AO } ] of the KS - DFT self - consistent calculation is set
to $ 10 ^ { - 5 } $ .
%For comparison, regular HF and KS-DFT calculations are performed with the same threshold.
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In order to compute the various density-functional
integrals that cannot be performed in closed form,
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a 51-point Gauss-Legendre quadrature is employed.
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In order to test the present eLDA functional we perform various sets of calculations.
To get reference excitation energies for both the single and double excitations, we compute full configuration interaction (FCI) energies with the Knowles-Handy FCI program described in Ref.~\onlinecite { Knowles_ 1989} .
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For the single excitations, we also perform time-dependent LDA (TDLDA)
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calculations [\ie , TDDFT with the LDA functional defined in Eq.~\eqref { eq:LDA} ].
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Its Tamm-Dancoff approximation version (TDA-TDLDA) is also considered. \cite { Dreuw_ 2005}
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Concerning the ensemble calculations, two sets of weight are tested: the zero-weight
(ground-state) limit where $ \bw = ( 0 , 0 ) $ and the
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equi-triensemble (or equal-weight state-averaged) limit where $ \bw = ( 1 / 3 , 1 / 3 ) $ .
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section { Results and discussion}
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\label { sec:res}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%% FIG 1 %%%
\begin { figure*}
\includegraphics [width=\linewidth] { EvsW_ n5}
\caption {
\label { fig:EvsW}
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Deviation from linearity of the weight-dependent KS-eLDA ensemble energy $ \E { eLDA } { ( \ew { 1 } , \ew { 2 } ) } $ with (dashed lines) and without (solid lines) ghost-interaction correction (GIC) for 5-boxium (\ie , $ \nEl = 5 $ ) with a box of length $ L = \pi / 8 $ (left), $ L = \pi $ (center), and $ L = 8 \pi $ (right).
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}
\end { figure*}
%%% %%% %%%
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First, we discuss the linearity of the computed (approximate)
ensemble energies.
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To do so, we consider 5-boxium with box lengths of $ L = \pi / 8 $ , $ L = \pi $ , and $ L = 8 \pi $ , which correspond (qualitatively at least) to the weak, intermediate, and strong correlation regimes, respectively.
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The deviation from linearity of the three-state ensemble energy
$ \E { } { ( \ew { 1 } , \ew { 2 } ) } $ (\ie , the deviation from the
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linearly-interpolated ensemble energy) is represented
in Fig.~\ref { fig:EvsW} as a function of $ \ew { 1 } $ or $ \ew { 2 } $ while
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fulfilling the restrictions on the ensemble weights to ensure the GOK
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variational principle [\ie , $ 0 \le \ew { 2 } \le 1 / 3 $ and $ \ew { 2 } \le \ew { 1 } \le ( 1 - \ew { 2 } ) / 2 $ ].
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To illustrate the magnitude of the ghost-interaction error, we report the KS-eLDA ensemble energy with and without GIC as explained above { [see Eqs.~\eqref { eq:Ew-GIC-eLDA} and \eqref { eq:Ew-eLDA} ]} .
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As one can see in Fig.~\ref { fig:EvsW} , without GIC, the
ensemble energy becomes less and less linear as $ L $
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gets larger, while the GIC reduces the curvature of the ensemble energy
drastically.
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%\manu{This
%is a strong statement I am not sure about. The nature of the excitation
%should also be invoked I guess (charge transfer or not, etc ...). If we look at the GIE:
%\beq
%\WHF[
%\bGam{\bw}]-\sum_{I\geq0}\ew{I}\WHF[ \bGam{(I)}]
%\eeq
%For a bi-ensemble ($w_1=w$) it can be written as
%\beq
%\dfrac{1}{2}\left[(w^2-1)W_0+w(w-2)W_1\right]+w(1-w)W_{01}
%\eeq
%If, for some reason, $W_0\approx W_1\approx W_{01}=W$, then the error
%reduces to $-W/2$, which is weight-independent (it fits for example with
%what you see in the weakly correlated regime). Such an assumption depends on the nature of the
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%excitation, not only on the correlation strength, right? Nevertheless,
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%when looking at your curves, this assumption cannot be made when the
%correlation is strong. It is not clear to me which integral ($W_{01}?$)
%drives the all thing.\\}
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It is important to note that, even though the GIC removes the explicit
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quadratic Hx terms from the ensemble energy, a non-negligible curvature
remains in the GIC-eLDA ensemble energy when the electron
correlation is strong. This is due to
(i) the correlation eLDA
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functional, which contributes linearly (or even quadratically) to the individual
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energies [see Eqs.~\eqref { eq:Taylor_ exp_ ind_ corr_ ener_ eLDA} and
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\eqref { eq:Taylor_ exp_ DDisc_ term} ], and (ii) the optimization of the
ensemble KS orbitals in the presence of ghost-interaction errors [see
Eqs.~\eqref { eq:min_ with_ HF_ ener_ fun} and \eqref { eq:WHF} ].
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%However, this orbital-driven error is small (in our case at
%least) \trashEF{as the correlation part of the ensemble KS potential $\delta
%\E{c}{\bw}[\n{}{}] /\delta \n{}{}(\br{})$ is relatively small compared
%to the Hx contribution}.\manu{Manu: well, I guess that the problem arises
%from the density matrices (or orbitals) that are used to compute
%individual Coulomb-exchange energies (I would not expect the DFT
%correlation part to have such an impact, as you say). The best way to check is to plot the
%ensemble energy without the correlation functional.}\\
%\\
%\manu{Manu: another idea. As far as I can see we do
%not show any individual energies (excitation energies are plotted in the
%following). Plotting individual energies (to be compared with the FCI
%ones) would immediately show if there is some curvature (in the ensemble
%energy). The latter would
%be induced by any deviation from the expected horizontal straight lines.}
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%%% FIG 2 %%%
\begin { figure*}
\includegraphics [width=\linewidth] { EIvsW_ n5}
\caption {
\label { fig:EIvsW}
KS-eLDA individual energies, $ \E { eLDA } { ( 0 ) } $ (black), $ \E { eLDA } { ( 1 ) } $ (red), and $ \E { eLDA } { ( 2 ) } $ (blue), as functions of the weights $ \ew { 1 } $ (solid) and $ \ew { 2 } $ (dashed) for 5-boxium (\ie , $ \nEl = 5 $ ) with a box of length $ L = \pi / 8 $ (left), $ L = \pi $ (center), and $ L = 8 \pi $ (right).}
\end { figure*}
%%% %%% %%%
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Figure \ref { fig:EIvsW} reports the behavior of the three KS-eLDA individual energies as functions of the weights.
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Unlike in the exact theory, we do not obtain
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straight horizontal lines when plotting these
energies, which is in agreement with
the curvature of the GIC-eLDA ensemble energy discussed previously. Interestingly, the
individual energies do not vary in the same way depending on the state
considered and the value of the weights.
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We see for example that, within the biensemble (\ie , $ \ew { 2 } = 0 $ ), the energies of
the ground and first excited-state increase with respect to the
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first-excited-state weight $ \ew { 1 } $ , thus showing that, in this
case, we
``deteriorate'' these states by optimizing the orbitals for the
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ensemble, rather than for each state separately. The reverse actually occurs for the ground state in the triensemble
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as $ \ew { 2 } $ increases. The variations in the ensemble
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weights are essentially linear or quadratic. They are induced by the
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eLDA correlation functional, as readily seen from
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Eqs.~\eqref { eq:Taylor_ exp_ ind_ corr_ ener_ eLDA} and
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\eqref { eq:Taylor_ exp_ DDisc_ term} . In the biensemble, the weight dependence of the first
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excited-state energy is reduced as the correlation increases. On the other hand, switching from a bi- to a triensemble
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systematically enhances the weight dependence, due to the lowering of the
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ground-state energy, as $ \ew { 2 } $ increases.
The reverse is observed for the second excited state.
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%%% FIG 3 %%%
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\begin { figure}
\includegraphics [width=\linewidth] { EvsL_ 5}
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\caption {
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\label { fig:EvsL}
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Excitation energies (multiplied by $ L ^ 2 $ ) associated with the single excitation $ \Ex { } { ( 1 ) } $ (bottom) and double excitation $ \Ex { } { ( 2 ) } $ (top) of 5-boxium for various methods and box lengths $ L $ .
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Graphs for additional values of $ \nEl $ can be found as { \SI } .
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}
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\end { figure}
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%%% %%% %%%
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Figure \ref { fig:EvsL} reports the excitation energies (multiplied by $ L ^ 2 $ ) for various methods and box lengths in the case of 5-boxium (\ie , $ \nEl = 5 $ ).
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Similar graphs are obtained for the other $ \nEl $ values and they can be found in the { \SI } alongside the numerical data associated with each method.
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For small $ L $ , the single and double excitations can be labeled as
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``pure'', as revealed by a thorough analysis of the FCI wavefunctions.
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In other words, each excitation is dominated by a sole, well-defined reference Slater determinant.
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However, when the box gets larger (\ie , as $ L $ increases), there is a strong mixing between the different excitation degrees.
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In particular, the single and double excitations strongly mix, which makes their assignment as single or double excitations more disputable. \cite { Loos_ 2019}
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This can be clearly evidenced by the weights of the different
configurations in the FCI wave function.\\
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% TITOU: shall we keep the paragraph below?
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%Therefore, it is paramount to construct a two-weight correlation functional
%(\ie, a triensemble functional, as we have done here) which
%allows the mixing of singly- and doubly-excited configurations.
%Using a single-weight (\ie, a biensemble) functional where only the ground state and the lowest singly-excited states are taken into account, one would observe a neat deterioration of the excitation energies (as compared to FCI) when the box gets larger.
%\titou{Titou might add results for the biensemble to illustrate this.}
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%\manu{Well, neglecting the second excited state is not the same as
%considering the $w_2=0$ limit. I thought you were referring to an
%approximation where the triensemble calculation is performed with
%the biensemble functional. This is not the same as taking $w_2=0$
%because, in this limit, you may still have a derivative discontinuity
%correction. The latter is absent if you truly neglect the second excited
%state in your ensemble functional. This should be clarified.}\\
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%\manu{Are the results in the supp mat? We could just add "[not
%shown]" if not. This is fine as long as you checked that, indeed, the
%results deteriorate ;-)}
%\manu{Should we add that, in the bi-ensemble case, the ensemble
%correlation derivative $\partial \epsilon^\bw_{\rm c}(n)/\partial w_2$
%is neglected (if this is really what you mean (?)). I guess that this is the reason why
%the second excitation energy would not be well described (?)}
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As shown in Fig.~\ref { fig:EvsL} , all methods provide accurate estimates of the excitation energies in the weak correlation regime (\ie , small $ L $ ).
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When the box gets larger, they start to deviate.
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For the single excitation, TDLDA is extremely accurate up to $ L = 2 \pi $ , but yields more significant errors at larger $ L $ by underestimating the excitation energies.
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TDA-TDLDA slightly corrects this trend thanks to error compensation.
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Concerning the eLDA functional, our results clearly evidence that the equiweight [\ie , $ \bw = ( 1 / 3 , 1 / 3 ) $ ] excitation energies are much more accurate than the ones obtained in the zero-weight limit [\ie , $ \bw = ( 0 , 0 ) $ ].
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This is especially true, in the strong correlation regime, for the single excitation
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which is significantly improved by using equal weights.
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The effect on the double excitation is less pronounced.
Overall, one clearly sees that, with
equal weights, KS-eLDA yields accurate excitation energies for both single and double excitations.
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This conclusion is verified for smaller and larger numbers of electrons
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(see { \SI } ).\\
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%\\
%\manu{Manu: now comes the question that is, I believe, central in this
%work. How important are the
%ensemble correlation derivatives $\partial \epsilon^\bw_{\rm
%c}(n)/\partial w_I$ that, unlike any functional
%in the literature, the eLDA functional contains. We have to discuss this
%point... I now see, after reading what follows that this question is
%addressed later on. We should say something here and then refer to the
%end of the section, or something like that ...}
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%%% FIG 4 %%%
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\begin { figure*}
\includegraphics [width=\linewidth] { EvsN}
\caption {
\label { fig:EvsN}
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Error with respect to FCI in single and double excitation energies for $ \nEl $ -boxium for various methods and electron numbers $ \nEl $ at $ L = \pi / 8 $ (left), $ L = \pi $ (center), and $ L = 8 \pi $ (right).
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}
\end { figure*}
%%% %%% %%%
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For the same set of methods, Fig.~\ref { fig:EvsN} reports the error (in \% ) in excitation energies (as compared to FCI) as a function of $ \nEl $ for three values of $ L $ ($ \pi / 8 $ , $ \pi $ , and $ 8 \pi $ ).
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We draw similar conclusions as above: irrespectively of the number of
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electrons, the eLDA functional with equal
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weights is able to accurately model single and double excitations, with
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a very significant improvement brought by the
equiensemble KS-eLDA orbitals as compared to their zero-weight
(\ie , conventional ground-state) analogs.
As a rule of thumb, in the weak and intermediate correlation regimes, we
see that the single
excitation obtained from equiensemble KS-eLDA is of
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the same quality as the one obtained in the linear response formalism
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(such as TDLDA). On the other hand, the double
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excitation energy only deviates
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from the FCI value by a few tenth of percent.
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Moreover, we note that, in the strong correlation regime
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(right graph of Fig.~\ref { fig:EvsN} ), the single excitation
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energy obtained at the equiensemble KS-eLDA level remains in good
agreement with FCI and is much more accurate than the TDLDA and TDA-TDLDA excitation energies which can deviate by up to $ 60 \% $ .
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This also applies to the double excitation, the discrepancy
between FCI and equiensemble KS-eLDA remaining of the order of a few percents in the strong correlation regime.
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These observations nicely illustrate the robustness of the
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GOK-DFT scheme in any correlation regime for both single and double excitations.
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This is definitely a very pleasing outcome, which additionally shows
that, even though we have designed the eLDA functional based on a
two-electron model system, the present methodology is applicable to any
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1D electronic system, \ie , a system that has more than two
electrons.
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%%% FIG 5 %%%
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\begin { figure*}
\includegraphics [width=\linewidth] { EvsL_ DD}
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\caption {
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\label { fig:EvsL_ DD}
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Error with respect to FCI (in \% ) associated with the single excitation $ \Ex { } { ( 1 ) } $ (bottom) and double excitation $ \Ex { } { ( 2 ) } $ (top) as a function of the box length $ L $ for 3-boxium (left), 5-boxium (center), and 7-boxium (right) at the KS-eLDA level with and without the contribution of the ensemble correlation derivative $ \DD { c } { ( I ) } $ .
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Zero-weight (\ie , $ \ew { 1 } = \ew { 2 } = 0 $ , red lines) and equiweight (\ie , $ \ew { 1 } = \ew { 2 } = 1 / 3 $ , blue lines) calculations are reported.
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}
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\end { figure*}
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%%% %%% %%%
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It is also interesting to investigate the influence of the
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correlation ensemble derivative contribution $ \DD { c } { ( I ) } $
to the $ I $ th excitation energy [see Eq.~\eqref { eq:DD-eLDA} ].
In our case, both single ($ I = 1 $ ) and double ($ I = 2 $ ) excitations are considered.
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To do so, we have reported in Fig.~\ref { fig:EvsL_ DD} , for $ \nEl = 3 $ , $ 5 $ , and $ 7 $ , the error percentage (with respect to FCI) as a function of the box length $ L $
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on the excitation energies obtained at the KS-eLDA level with and without $ \DD { c } { ( I ) } $ [\ie , the last term in Eq.~\eqref { eq:Om-eLDA} ].
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%\manu{Manu: there is something I do not understand. If you want to
%evaluate the importance of the ensemble correlation derivatives you
%should only remove the following contribution from the $K$th KS-eLDA
%excitation energy:
%\beq\label{eq:DD_term_to_compute}
%\int \n{\bGam{\bw}}{}(\br{})
% \left. \pdv{\e{c}{\bw}(\n{}{})}{\ew{K}} \right|_{\n{}{}=\n{\bGam{\bw}}{}(\br{})} d\br{}
%\eeq
%%rather than $E^{(I)}_{\rm HF}$
%}
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We first stress that although for $ \nEl = 3 $ both single and double excitation energies are
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systematically improved (as the strength of electron correlation
increases) when
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taking into account
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the correlation ensemble derivative, this is not
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always the case for larger numbers of electrons.
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For 3-boxium, in the zero-weight limit, the correlation ensemble derivative is
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significantly larger for the single
excitation as compared to the double excitation; the reverse is observed in the equal-weight triensemble
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case.
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However, for 5- and 7-boxium, it hardly
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influences the double excitation (except when the correlation is strong), and slightly deteriorates the single excitation in the intermediate and strong correlation regimes.
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This non-systematic behavior in terms of the number of electrons might
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be a consequence of how we constructed eLDA.
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Indeed, as mentioned in Sec.~\ref { sec:eDFA} , the weight dependence of
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the eLDA functional is based on a \textit { two-electron} finite uniform electron gas.
Incorporating an $ \nEl $ -dependence in the functional through the
curvature of the Fermi hole, in the spirit of Ref.~\onlinecite { Loos_ 2017a} , would be
valuable in this respect. This is left for future work.
%\\
%\manu{Manu: I am sorry to insist but I have a real problem with what follows. If
%we look at the N=3 results, one has the impression that, indeed, for the
%single excitation, a zero-weight calculation with the ensemble derivative
%is almost equivalent to an equal-weight calculation without the
%derivative. This is not the case for $N=5$ or 7, maybe because our
%derivative is based on two electrons. }\\
%{\it
%Importantly, \titou{for the single excitation}, one realizes that the magnitude of the correlation ensemble
%derivative is \trashPFL{much} smaller in the case of equal-weight calculations (as
%compared to the zero-weight calculations).
%%\manu{Manu: well, this is not
%%really the case for the double excitation, right? I would remove this
%%sentence or mention the single excitation explicitly.}
%This could explain why equiensemble calculations are clearly more
%accurate \titou{for the single excitation} as it reduces the influence of the ensemble correlation derivative:
%for a given method, equiensemble orbitals partially remove the burden
%of modelling properly the ensemble correlation derivative.
%}\\
%\manu{Manu: I propose to rephrase this part as follows:}\\
%\\
Interestingly, for the single excitation in 3-boxium, the magnitude of the correlation ensemble
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derivative is substantially reduced when switching from a zero-weight to
an equal-weight calculation, while giving similar excitation energies,
even in the strongly correlated regime. A possible interpretation is
that, at least for the single excitation, equiensemble orbitals partially remove the burden
of modelling properly the correlation ensemble derivative.
This conclusion does not hold for larger
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numbers of electrons ($ N = 5 $ or $ 7 $ ), possibly because eLDA extracts density-functional correlation ensemble
derivatives from a two-electron uniform electron gas, as mentioned previously.
For the double excitation, the ensemble derivative remains important, even in
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the equiensemble case.
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To summarize, the equiensemble calculation
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is always more accurate than a zero-weight
(\ie , a conventional ground-state DFT) one, with or without including the ensemble
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derivative correction. Note that the second term on the right-hand side
of
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Eq.~\eqref { eq:Om-eLDA} , which involves the weight-dependent correlation
potential and the density difference between ground and excited states,
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has a negligible effect on the excitation energies (results not
shown).\\
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%\manu{Manu: Is this
%something that you checked but did not show? It feels like we can see
%this in the Figure but we cannot, right?}
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%\manu{Manu: well, we
%would need the exact derivative value to draw such a conclusion. We can
%only speculate. Let us first see how important the contribution in
%Eq.~\eqref{eq:DD_term_to_compute} is. What follows should also be
%updated in the light of the new results.}
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%%% FIG 6 %%%
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\begin { figure}
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\includegraphics [width=\linewidth] { EvsN_ DD}
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\caption {
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\label { fig:EvsN_ DD}
Error with respect to FCI in single and double excitation energies for $ \nEl $ -boxium (with a box length of $ L = 8 \pi $ ) as a function of the number of electrons $ \nEl $ at the KS-eLDA level with and without the contribution of the ensemble correlation derivative $ \DD { c } { ( I ) } $ .
Zero-weight (\ie , $ \ew { 1 } = \ew { 2 } = 0 $ , red lines) and equiweight (\ie , $ \ew { 1 } = \ew { 2 } = 1 / 3 $ , blue lines) calculations are reported.
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}
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\end { figure}
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%%% %%% %%%
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Finally, in Fig.~\ref { fig:EvsN_ DD} , we report the same quantities as a function of the electron number for a box of length $ 8 \pi $ (\ie , in the strong correlation regime).
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The difference between the solid and dashed curves
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undoubtedly show that the
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correlation ensemble derivative has a rather significant impact on the double
excitation (around $ 10 \% $ ) with a slight tendency of worsening the excitation energies
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in the case of equal weights, as the number of electrons
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increases. It has a rather large influence (which decreases with the
number of electrons) on the single
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excitation energies obtained in the zero-weight limit, showing once
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again that the usage of equal weights has the benefit of significantly reducing the magnitude of the correlation ensemble derivative.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section { Concluding remarks}
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\label { sec:conclusion}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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A local and ensemble-weight-dependent correlation density-functional approximation
(eLDA) has been constructed in the context of GOK-DFT for spin-polarized
triensembles in
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1D. The approach is general and can be extended to real
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(three-dimensional)
systems~\cite { Loos_ 2009,Loos_ 2009c,Loos_ 2010,Loos_ 2010d,Loos_ 2017a}
and larger ensembles in order to
model excited states in molecules and solids. Work is currently in
progress in this direction.
Unlike any standard functional, eLDA incorporates derivative
discontinuities through its weight dependence. The latter originates
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from the finite uniform electron gas on which eLDA is
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(partially) based. The KS-eLDA scheme, where exact individual
exchange energies are
combined with the eLDA correlation functional , delivers accurate excitation energies for both
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single and double excitations, especially when an equiensemble is used.
In the latter case, the same weights are assigned to each state belonging to the ensemble.
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The improvement on the excitation energies brought by the KS-eLDA scheme is particularly impressive in the strong correlation regime where usual methods, such as TDLDA, fail.
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We have observed that, although the correlation ensemble derivative has a
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non-negligible effect on the excitation energies (especially for the
single excitations), its magnitude can be significantly reduced by
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performing equiweight calculations instead of zero-weight
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calculations.
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Let us finally stress that the present methodology can be extended to other types of ensembles like, for example, the
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$ \nEl $ -centered ones, \cite { Senjean_ 2018,Senjean_ 2020} thus allowing for the design of a LDA-type functional for the
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calculation of ionization potentials, electron affinities, and
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fundamental gaps.
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Like in the present
eLDA, such a functional would incorporate the infamous derivative
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discontinuity contribution to the fundamental gap through its explicit weight
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dependence. We hope to report on this in the near future.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\section * { Supplementary material}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
See { \SI } for the additional details about the construction of the functionals, raw data and additional graphs.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\begin { acknowledgements}
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The authors thank Bruno Senjean and Clotilde Marut for stimulating discussions.
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This work has been supported through the EUR grant NanoX ANR-17-EURE-0009 in the framework of the \textit { ``Programme des Investissements d'Avenir''.}
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\end { acknowledgements}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\bibliography { eDFT}
\end { document}