Bridging Single- and Multireference Domains for Electron Correlation: Spin-Extended Coupled Electron Pair Approximation

Tsuchimochi, Takashi; Ten‐no, Seiichiro

doi:10.1021/acs.jctc.7b00073

Cited by 24 publications

(33 citation statements)

References 116 publications

(278 reference statements)

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“…While there have been attempts to merge a symmetry-projected mean-field reference with a symmetry-adapted cluster operator [17,18], practical attempts to projectively restore the symmetries of a broken-symmetry coupled cluster wave function have only been made in the past few years. Duguet [19,20] and Scuseria [21] have proposed independent ways to achieve this, and Tsuchimochi and Ten-no have provided a third approach [22], albeit so far at the linearized coupled cluster level.…”

Section: Introductionmentioning

confidence: 99%

Particle-number projected Bogoliubov-coupled-cluster theory: Application to the pairing Hamiltonian

et al. 2019

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Background: While coupled cluster theory accurately models weakly correlated quantum systems, it often fails in the presence of strong correlations where the standard mean-field picture is qualitatively incorrect. In many cases, these failures can be largely ameliorated by permitting the mean-field reference to break physical symmetries. Symmetry-broken coupled cluster, e.g. Bogoliubov coupled cluster, theory can indeed provide reasonably accurate energetic predictions, but the broken symmetry can compromise the quality of the resulting wave function and predictions of observables other than the energy.Purpose: Merging symmetry projection and coupled cluster theory is therefore an appealing way to describe strongly correlated systems. One indeed expects to inherit and further improve the energetic accuracy of brokensymmetry coupled cluster while retaining proper symmetries.Methods: Independently, two different but related formalisms have been recently proposed to achieve this goal. The two formalisms are contrasted in this manuscript, with results tested on the Richardson pairing Hamiltonian. While the present paper focuses on the breaking and restoration of U (1) global-gauge symmetry associated with particle number conservation, the symmetry-projected coupled cluster formalism is applicable to other symmetries such as rotational (i.e. spin) symmetry.Results: Both formalisms are based on the disentangled cluster representation of the symmetry-rotated coupled cluster wavefunction. However, they differ in the way that the disentangled clusters are solved. One approach sets up angle-dependent coupled cluster equations, while the other involves first-order ordinary differential equations. The latter approach yields energies and occupation probabilities significantly better than those of numberprojected BCS and BCS coupled cluster and, when the disentangled clusters are truncated at low excitation levels, has a computational cost not too much larger than that of BCS coupled cluster. Conclusions:The high quality of results presented in this manuscript indicates that symmetry-projected coupled cluster is a promising method that can accurately describe both weakly and strongly correlated finite many-fermion systems.

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Section: Introductionmentioning

confidence: 99%

Particle-number projected Bogoliubov-coupled-cluster theory: Application to the pairing Hamiltonian

et al. 2019

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“…In Table I the uncorrected and corrected second-order energies, E 2 and L (Eqs. (24) and (30)). The level-shift correction is essential to keep the qualitative results of rSUPT2.…”

Section: B Multiple Bond Dissociation: H2o and N2mentioning

confidence: 94%

“…Therefore, the DIIS convergence is somewhat slow with the present implementation. Nevertheless, other preconditioning schemes are available to improve the convergence behavior, 24 and we will test and report their performances in a separate paper.…”

Section: Computational Detailsmentioning

confidence: 99%

Second-Order Perturbation Theory with Spin-Symmetry-Projected Hartree–Fock

Tsuchimochi

Ten‐no

2019

J. Chem. Theory Comput.

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We propose two different schemes for second-order perturbation theory with spin-projected Hartree-Fock. Both schemes employ the same ansatz for the first-order wave function, which is a linear combination of spin-projected configurations. The first scheme is based on the normal-ordered projected Hamiltonian, which is partitioned into the Fock-like component and the remaining two-particle-like contribution. In the second scheme, the generalized Fock operator is used to construct a spin-free zeroth-order Hamiltonian. To avoid the intruder state problem, we adopt the level-shift techniques frequently used in other multi-reference perturbation theories. We describe both real and imaginary shift schemes and compare their performances on small systems. Our results clearly demonstrate the superiority of the second perturbation scheme with an imaginary shift over other proposed approaches in various aspects, giving accurate potential energy curves, spectroscopic constants, and singlet-triplet splitting energies. We also apply these methods to the calculation of spin gaps of transition metal complexes as well as the potential energy curve of the chromium dimer.

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“…The estimated gaps of ECISD and ECISD+Q are 7.9 and 22.8 kcal mol -1 , which are somewhat smaller than the SC-LCTSD and RASPT2 results. We have also performed a variety of spin-extended linearized CC calculations [10] to capture size-consistent effects, but found that their correlation energies diverge for this system because of intruder states; the ECISD first excited state lies relatively close to the ground state. While EACCSD is stable in this respect, and is deemed to be a better approximation than ECISD, it gave a potential curve that is quite similar to ECISD+Q, with a gap of 23.1 kcal mol -1 .…”

Section: Mn Dimermentioning

confidence: 99%

“…With this form, SUHF became a versatile tool for studying degenerate systems with the same computational scaling as HF. [6][7][8][9] Spin-projection on broken-symmetry CC, which we call spinextended CC (ECC), [10,11] is therefore an attractive candidate for describing both static and dynamical correlation effects (we have to clarify that it is different from the extended coupled-cluster of Arponen, which was derived from the bivariational principle in 1983 [12] ) and many authors have explored its potential. [11,13,14] However, challenges remain in combining CC and spin-projection, with two particular difficulties.…”

Section: Introductionmentioning

confidence: 99%

Extending spin‐symmetry projected coupled‐cluster to large model spaces using an iterative null‐space projection technique

Tsuchimochi

Ten‐no

2018

J Comput Chem

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Recently, we introduced an orbital‐invariant approximate coupled‐cluster (CC) method in the spin‐projection manifold. The multi‐determinantal property of spin‐projection means that the parametrization in the spin‐extended CC (ECC) ansatz is nonorthogonal and overcomplete. Therefore, the linear dependencies must be removed by an orthogonalization procedure to obtain meaningful solutions. Multi‐reference methods often achieve this by diagonalizing a metric of the equation system, but this is not feasible with ECC because of the enormous size of the metric, a consequence of the incomplete active space of the spin‐projected Hartree–Fock reference. As a result, the applicability of ECC has been limited to small benchmark systems, for which the ansatz was shown to be superior to the configuration interaction and linearized approximations. In this article, we provide a solution to this problem that completely avoids the metric diagonalization by iteratively projecting out its null‐space from the working equations. As the additional computational cost required for this iterative projection is only marginal, it greatly expands the application range of ECC. We demonstrate the potential of approximate ECC by studying the complete basis set limit of F2 and transition metal complexes such as NiO, Mn2, and [Cu2O2]2+, which have all been hindered by the prohibitively large metric size. We also identify the potential inadequacy of the molecular orbitals given by spin‐projected Hartree–Fock in some cases, and propose possible solutions. © 2018 Wiley Periodicals, Inc.

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Bridging Single- and Multireference Domains for Electron Correlation: Spin-Extended Coupled Electron Pair Approximation

Cited by 24 publications

References 116 publications

Particle-number projected Bogoliubov-coupled-cluster theory: Application to the pairing Hamiltonian

Particle-number projected Bogoliubov-coupled-cluster theory: Application to the pairing Hamiltonian

Second-Order Perturbation Theory with Spin-Symmetry-Projected Hartree–Fock

Extending spin‐symmetry projected coupled‐cluster to large model spaces using an iterative null‐space projection technique

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