Quantum Monte Carlo studies of covalent and metallic clusters: Accuracy of density functional approximations

Hsing, Cheng‐Rong; Wei, C. M.; Drummond, Neil; Needs, R. J.

doi:10.1103/physrevb.79.245401

Cited by 38 publications

(24 citation statements)

References 39 publications

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“…Even for some covalent clusters, such as C 20 or B 20 , several commonlyused functionals have been shown to be highly unreliable in predicting geometries and relative ground-state energies. 18 Nevertheless, in most cases, DFT is essentially the most accurate method available due to its favorable computational cost.…”

mentioning

confidence: 99%

Failure of Conventional Density Functionals for the Prediction of Molecular Crystal Polymorphism: A Quantum Monte Carlo Study

Hongo

Watson

Sánchez‐Carrera

et al. 2010

J. Phys. Chem. Lett.

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We have applied the diffusion Monte Carlo method, for the first time, to an organic molecular crystal (para-diiodobenzene) in order to determine the relative stability of its two well-known polymorphs. The DMC result predicts that the R phase is more stable than the β phase at zero temperature, in agreement with experiment. In comparison, we evaluated four commonly used local, semilocal, and hybrid density functionals, including an empirical correction to include the effects of dispersion. We conclude that while density functional theory may provide the most practical method for estimating the effects of electron correlation, conventional functionals which do not accurately describe noncovalent interactions may not be considered reliable for determining highly accurate energies in such systems.

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mentioning

confidence: 99%

Failure of Conventional Density Functionals for the Prediction of Molecular Crystal Polymorphism: A Quantum Monte Carlo Study

Hongo

Watson

Sánchez‐Carrera

et al. 2010

J. Phys. Chem. Lett.

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“…To quantify to which extent the DFT approaches can predict the relative stability of the cluster isomers, we perform the correlation analysis introduced in Ref. [4]. The correlation (corr) between the DFT and DMC energies and the relative amplitude (L) is given by…”

Section: Resultsmentioning

confidence: 99%

“…The question arises how reliable are the widely used density functional theory (DFT) based approaches for the determination of these semi-empirical potentials, and how accurately they are able to predict, for example, the relative energies of small cluster isomers. In a recent study, Hsing and coworkers [4] have shown that the DFT methods are able to describe correctly the relative stability of monoatomic metallic aluminum and copper cluster isomers, but fail in predicting the relative stability of covalently bonded carbon and boron isomers. For benchmark calculations, the diffusion Monte Carlo (DMC) method was used, which is the most accurate method for system of interacting electrons known up to now.…”

Section: Introductionmentioning

confidence: 99%

Quantum Monte Carlo vs. Density Functional Methods for the Prediction of Relative Energies of Small Si-C Clusters

Szwacki

Majewski

2011

Acta Phys. Pol. A

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In the present paper, we assess the accuracy of popular and widely used approaches based on density functional theory by relating them to the most accurate at present quantum Monte Carlo calculations. As the test case, we consider the relative stability of small SinCm isomers. We find out that none of the studied DFT approaches employing local, semilocal, or even hybrid functionals are able to predict correctly the relative stability of the isomers.

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“…Monte Carlo confirmation: Different isomers of boron clusters B 18 were also investigated by Hsing et al 72 using diffusion quantum Monte Carlo methods (DMC) to calculate their relative energies. The aim of this work was first to examine the accuracy of various density functional theory (DFT) exchange-correlation (XC) functionals in predicting the relative energies of cluster isomers and to provide new benchmark data.…”

Section: Boron Clusters B N (16 R N R 20)mentioning

confidence: 99%

“…Monte Carlo confirmation: In order to examine the accuracy of various DFT exchange-correlation XC functionals in predicting the relative energies of cluster isomers and to provide new benchmark data, Hsing et al 72 16,18,20,24) using quantum chemical methods.…”

Section: Boron Clusters B N (16 R N R 20)mentioning

confidence: 99%

Towards novel boron nanostructural materials

Boustani¹

Chemical Modelling

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Nanostructures are linked to many areas of science and technology. A cornerstone of our current research is the practical development of boron cluster-based, nanostructured Materials-by-Design. It is now possible to imagine and predictably model properties, synthesis procedures, manufacturing processes, and to functionally integrate engineering principles. Super-properties such as hardness, wear, coating, as a form of resistance to many attacks (e.g. corrosion), conductivity, spin and energy conversion/ storage, neutron protection and absorption, radiation shielding, armor, hardening, enforce, nanoenergetic, propulsion and glue materials, not to mention the boron neutron capture therapy in medicine, will benefit from the functionalization and industrialization of boron clusters and predicted nanostructures. The experimentally observed physical manifestations of a number of these clusters and nanostructures and related properties are consistent with our theoretical models. Early experiments have demonstrated the near-term viability of controlled synthesis for specific engineering properties.

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Quantum Monte Carlo studies of covalent and metallic clusters: Accuracy of density functional approximations

Cited by 38 publications

References 39 publications

Failure of Conventional Density Functionals for the Prediction of Molecular Crystal Polymorphism: A Quantum Monte Carlo Study

Failure of Conventional Density Functionals for the Prediction of Molecular Crystal Polymorphism: A Quantum Monte Carlo Study

Quantum Monte Carlo vs. Density Functional Methods for the Prediction of Relative Energies of Small Si-C Clusters

Towards novel boron nanostructural materials

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