Numerical and Theoretical Aspects of the DMRG-TCC Method Exemplified by the Nitrogen Dimer

Faulstich, Fabian M.; Maté, Mihály; Laestadius, Andre; Csirik, Mihaly Andras; Veis, Libor; Antalík, Andrej; Brabec, Jiří; Schneider, Reinhold; Pittner, Jiřı́; Kvaal, Simen; Legeza, Örs

doi:10.1021/acs.jctc.8b00960

Cited by 55 publications

(67 citation statements)

References 104 publications

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“…This caveat will be further discussed in Section 3.3. We also refer to [10] for a case study on the N 2 molecule illustrating the TCC method's sensitivity to the CAS choice.…”

Section: The Tailored Coupled-cluster Methodmentioning

confidence: 99%

“…Indeed, f (t; t CAS ) = P Vext f CC (t ⊕ t CAS ) with the orthogonal projection P Vext onto V ext , relates the TCC function to the classical CC function in Eq. (10). Note that the CAS-part of the cluster amplitudes is still fixed.…”

Section: The Tailored Coupled-cluster Methodmentioning

confidence: 99%

“…The DMRG method [45] is a high accuracy tool for statically correlated systems [7], nonetheless, for dynamically correlated problems it requires high computational resources making a wide-ranging application-at this time-intractable. Hence, it is the symbiosis of the DMRG and the CC method that creates a high efficiency scheme suitable for multireference systems [42,43,44,10,2,22]. Granted that the DMRG-TCCSD method is the major motivation for the following analysis, we highlight that the applicability of this article's results exceeds the DMRG-TCCSD method and, more generally, the TNS-TCC method.This paper is organized as follows.…”

mentioning

confidence: 91%

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Analysis of the Tailored Coupled-Cluster Method in Quantum Chemistry

Faulstich¹,

Laestadius²,

Legeza³

et al. 2019

SIAM J. Numer. Anal.

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In quantum chemistry, one of the most important challenges is the static correlation problem when solving the electronic Schrödinger equation for molecules in the Born-Oppenheimer approximation. In this article, we analyze the tailored coupled-cluster method (TCC), one particular and promising method for treating molecular electronic-structure problems with static correlation. The TCC method combines the single-reference coupled-cluster (CC) approach with an approximate reference calculation in a subspace [complete active space (CAS)] of the considered Hilbert space that covers the static correlation. A one-particle spectral gap assumption is introduced, separating the CAS from the remaining Hilbert space. This replaces the nonexisting or nearly nonexisting gap between the highest occupied molecular orbital and the lowest unoccupied molecular orbital usually encountered in standard single-reference quantum chemistry. The analysis covers, in particular, CC methods tailored by tensor-network states (TNS-TCC methods). The problem is formulated in a nonlinear functional analysis framework, and, under certain conditions such as the aforementioned gap, local uniqueness and existence are proved using Zarantonello's lemma. From the Aubin-Nitscheduality method, a quadratic error bound valid for TNS-TCC methods is derived, e.g., for lineartensor-network TCC schemes using the density matrix renormalization group method.Even if most molecules are single-reference systems in their equilibrium configuration, multireference character arises even in the simplest of chemical reactions, e.g., dissociation of N 2 . Yet, the static correlation problem is a long-lasting challenge in quantum chemistry. Many different MRCC approaches have been formulated to deal with the problem of static correlation. However, aside from formal difficulties and implementational complications, none of these methods have become a widely applicable tool. A review of different MRCC approaches is beyond the scope of this article, and we refer to Lyakh et al.[26] for a detailed description of the different benefits and disadvantages.We are here concerned with an MRCC method that is based on the single-reference methodology (also called an externally corrected ansatz): The tailored CC (TCC) method extends a precomputed solution for a chosen subsystem of the full system by including further electron correlations via CC theory. We refer to the subsystem as the complete active space (CAS) and to the remaining system as the external space. Given the single-reference CC method's major drawback, this subsystem needs to contain the static correlations. Consequently, the TCC method can be seen as a special type of an embedding method. Mathematically this corresponds to a division of excitation operators in two disjoint sub-algebras [19]. Nevertheless, in comparison with other "genuine" MRCC schemes, the TCC method suffers from the drawback that it is based on a single-reference theory and therewith introduces a certain bias towards a particular reference determinant....

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“…This caveat will be further discussed in Section 3.3. We also refer to [10] for a case study on the N 2 molecule illustrating the TCC method's sensitivity to the CAS choice.…”

Section: The Tailored Coupled-cluster Methodmentioning

confidence: 99%

Section: The Tailored Coupled-cluster Methodmentioning

confidence: 99%

mentioning

confidence: 91%

See 1 more Smart Citation

Analysis of the Tailored Coupled-Cluster Method in Quantum Chemistry

Faulstich¹,

Laestadius²,

Legeza³

et al. 2019

SIAM J. Numer. Anal.

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“…Very recently, a tailored coupled-cluster variant was proposed in combination with DMRG wave functions that reduces the multi-configurational coupled-cluster expressions to their single-configurational counterpart. [45][46][47] The multi-configurational effect is then included by constraining the amplitudes of excitations within the active space to those obtained from the DMRG calculation. Future work on this approach needs to show how universally applicable it actually is for strong multi-configurational cases that require large active spaces and large orbital basis sets.…”

Section: Introductionmentioning

confidence: 99%

Semiclassical Dispersion Corrections Efficiently Improve Multiconfigurational Theory with Short-Range Density-Functional Dynamic Correlation

Stein

Reiher

2020

J. Phys. Chem. A

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Multi-configurational wave functions are known to describe electronic structure across a Born-Oppenheimer surface qualitatively correct. However, for quantitative reaction energies, dynamical correlation originating from the many configurations involving excitations out of the restricted orbital space, the active space, must be considered. Standard procedures involve approximations that eventually limit the ultimate accuracy achievable (most prominently, multireference perturbation theory). At the same time, the computational cost increase dramatically due to the necessity to obtain higher-order reduced density matrices. It is this disproportion that leads us here to propose a MC-srDFT-D hybrid approach of semiclassical dispersion (D) corrections to cover long-range dynamical correlation in a multi-configurational (MC) wave function theory which may include short-range (sr) dynamical correlation by density functional theory (DFT) without double counting. We demonstrate that the reliability of this approach is very good (at negligible cost), especially when considering that standard second-order multi-reference perturbation theory usually overestimates dispersion interactions.

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“…These include density matrix renormalization group (DMRG) method 35,36 , which variationally optimizes wave functions in the form of matrix product states (MPS). 37 Other important examples represent characterization of electron correlation into its static (strong) and dynamic contributions 9 , automatic (black-box) selection of the active spaces 1, 6,17,23,24,38 , or the self-adaptive tensor network states with multi-site correlators 25 , all of which harness single-and two-orbital entanglement entropies. Last but not least, correlation measures based on the single-and two-orbital entanglement entropies have also been employed for the purposes of bond analysis 10,20 .…”

Section: Introductionmentioning

confidence: 99%

Quantum information-based analysis of electron-deficient bonds

Brandejs

Veis

Szalay

et al. 2019

The Journal of Chemical Physics

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Recently, the correlation theory of the chemical bond was developed, which applies concepts of quantum information theory for the characterization of chemical bonds, based on the multiorbital correlations within the molecule. Here for the first time, we extend the use of this mathematical toolbox for the description of electron-deficient bonds. We start by verifying the theory on the textbook example of a molecule with three-center two-electron bonds, namely the diborane(6). We then show that the correlation theory of the chemical bond is able to properly describe bonding situation in more exotic molecules which have been synthetized and characterized only recently, in particular the diborane molecule with four hydrogen atoms [diborane(4)] and neutral zerovalent s-block beryllium complex, whose surprising stability was attributed to a strong three-center twoelectron π bond stretching across the C-Be-C core. Our approach is of a high importance especially in the light of a constant chase after novel compounds with extraordinary properties where the bonding is expected to be unusual.

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Numerical and Theoretical Aspects of the DMRG-TCC Method Exemplified by the Nitrogen Dimer

Cited by 55 publications

References 104 publications

Analysis of the Tailored Coupled-Cluster Method in Quantum Chemistry

Analysis of the Tailored Coupled-Cluster Method in Quantum Chemistry

Semiclassical Dispersion Corrections Efficiently Improve Multiconfigurational Theory with Short-Range Density-Functional Dynamic Correlation

Quantum information-based analysis of electron-deficient bonds

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