<i>GW</i>100: A Plane Wave Perspective for Small Molecules

Maggio, Emanuele; Liu, Peitao; Setten, Michiel J. van; Kresse, Georg

doi:10.1021/acs.jctc.6b01150

Cited by 91 publications

(172 citation statements)

References 140 publications

(127 reference statements)

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“…34,39,40 For GW calculations on solids validation studies usually however restrict to one code and only a limited amount of systems. 33,[41][42][43] A systematic evaluation of the accuracy of the method is hence tedious at best.…”

Section: 37mentioning

confidence: 99%

Automation methodologies and large-scale validation for GW : Towards high-throughput GW calculations

et al. 2017

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The search for new materials, based on computational screening, relies on methods that accurately predict, in an automatic manner, total energy, atomic-scale geometries, and other fundamental characteristics of materials. Many technologically important material properties directly stem from the electronic structure of a material, but the usual workhorse for total energies, namely density-functional theory, is plagued by fundamental shortcomings and errors from approximate exchange-correlation functionals in its prediction of the electronic structure. At variance, the GW method is currently the state-of-the-art ab initio approach for accurate electronic structure. It is mostly used to perturbatively correct density-functional theory results, but is however computationally demanding and also requires expert knowledge to give accurate results. Accordingly, it is not presently used in high-throughput screening: fully automatized algorithms for setting up the calculations and determining convergence are lacking. In this work we develop such a method and, as a first application, use it to validate the accuracy of G0W0 using the PBE starting point, and the Godby-Needs plasmon pole model (G0W GN 0 @PBE), on a set of about 80 solids. The results of the automatic convergence study utilized provides valuable insights. Indeed, we find correlations between computational parameters that can be used to further improve the automatization of GW calculations. Moreover, we find that G0W GN 0 @PBE shows a correlation between the PBE and the G0W GN 0

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Section: 37mentioning

confidence: 99%

Automation methodologies and large-scale validation for GW : Towards high-throughput GW calculations

et al. 2017

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“…However, we also observe that, in some cases, unphysical irregularities on the ground-state PES, which are due to the appearance of a satellite resonance with a weight similar to that of the GW quasiparticle peak. [78][79][80][81][82] In order to compute the neutral (optical) excitations of the system and their associated oscillator strengths, the BSE expresses the two-body propagator 4,83 L(1, 2, 1 , 2 ) = L 0 (1, 2, 1 , 2 )…”

mentioning

confidence: 99%

“…This shortcoming has been thoroughly described in several previous studies. [78][79][80][81][82] We believe that this central issue must be resolved if one wants to expand the applicability of the present method.…”

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confidence: 99%

Pros and Cons of the Bethe–Salpeter Formalism for Ground-State Energies

Loos

Scemama

Duchemin

et al. 2020

J. Phys. Chem. Lett.

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The combination of the many-body Green's function GW approximation and the Bethe-Salpeter equation (BSE) formalism has shown to be a promising alternative to time-dependent density-functional theory (TD-DFT) for computing vertical transition energies and oscillator strengths in molecular systems. The BSE formalism can also be employed to compute ground-state correlation energies thanks to the adiabatic-connection fluctuationdissipation theorem (ACFDT). Here, we study the topology of the ground-state potential energy surfaces (PES) of several diatomic molecules near their equilibrium bond length. Thanks to comparisons with state-of-art computational approaches (CC3), we show that ACFDT@BSE is surprisingly accurate, and can even compete with lower-order coupled cluster methods (CC2 and CCSD) in terms of total energies and equilibrium bond distances for the considered systems. However, we sometimes observe unphysical irregularities on the groundstate PES in relation with difficulties in the identification of a few GW quasiparticle energies.

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“…The algorithm is also relevant for condensed matter ab initio applications in periodic systems that require high precision, such as GF2 9-17 and Hedin's GW [18][19][20][21][22][23][24][25][26] . This is a promising venue for future research.…”

Section: Discussionmentioning

confidence: 99%

Legendre-spectral Dyson equation solver with super-exponential convergence

Dong

Zgid

Gull

et al. 2020

The Journal of Chemical Physics

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Quantum many-body systems in thermal equilibrium can be described by the imaginary time Green's function formalism. However, the treatment of large molecular or solid ab inito problems with a fully realistic Hamiltonian in large basis sets is hampered by the storage of the Green's function and the precision of the solution of the Dyson equation. We present a Legendre-spectral algorithm for solving the Dyson equation that addresses both of these issues. By formulating the algorithm in Legendre coefficient space, our method inherits the known faster-than-exponential convergence of the Green's function's Legendre series expansion. In this basis, the fast recursive method for Legendre polynomial convolution, enables us to develop a Dyson equation solver with quadratic scaling. We present benchmarks of the algorithm by computing the dissociation energy of the helium dimer He 2 within dressed second-order perturbation theory. For this system, the application of the Legendre spectral algorithm allows us to achieve an energy accuracy of 10 −9 E h with only a few hundred expansion coefficients. arXiv:2001.11603v2 [cond-mat.str-el] 5 Apr 2020

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GW100: A Plane Wave Perspective for Small Molecules

Cited by 91 publications

References 140 publications

Automation methodologies and large-scale validation for GW : Towards high-throughput GW calculations

Automation methodologies and large-scale validation for GW : Towards high-throughput GW calculations

Pros and Cons of the Bethe–Salpeter Formalism for Ground-State Energies

Legendre-spectral Dyson equation solver with super-exponential convergence

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