Nonlocal kinetic energy functional from the jellium-with-gap model: Applications to orbital-free density functional theory

Constantin, Lucian A.; Fabiano, Eduardo; Sala, Fabio Della

doi:10.1103/physrevb.97.205137

Cited by 41 publications

(42 citation statements)

References 126 publications

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“…The non-local functionals have been quite successful in describing simple metals and some semiconductors with pseudopotentials (discussed later in this chapter) due to better description of linear response. The general trend seems to imply that while the non-local functionals do achieve better performance, improvements do come at the cost of specialization to a certain type of system [47,48,49]. Semilocal functionals do have a lower performance if we directly compare the best performing non-local functional and best performing semilocal on a chosen material but semilocal functionals are easily applied to any type of system (periodic, isolated) and have a competitive average performance [50,51].…”

Section: Orbital-free Frameworkmentioning

confidence: 99%

Semilocal kinetic energy functionals with parameters from neutral atoms

Lehtomäki

Lopez-Acevedo

2019

Phys. Rev. B

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The author implemented the Englert-Schwinger model, collected the data, and analyzed the results. Manuscript was written jointly. Publication II: "Large-Z limit in atoms and solids from first principles" The author ran the DFT simulations, collected the data and analyzed the results. Manuscript was written jointly. Publication III: "Semilocal kinetic energy functionals with parameters from neutral atoms" The author implemented the kinetic energy functionals, collected the data and analyzed the results. Manuscript was written jointly. Publication IV: "Boron doping in gallium oxide from first principles" The author ran the DFT simulations, collected the data, and analyzed the results. Manuscript was written jointly.

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Section: Orbital-free Frameworkmentioning

confidence: 99%

Semilocal kinetic energy functionals with parameters from neutral atoms

Lehtomäki

Lopez-Acevedo

2019

Phys. Rev. B

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“…Starting from the most stable structure, one atom in the center region (or in the edge region) is moved step by step in one of the degrees of freedom, such as the X-axis, while the Y- and Z-coordinates and all other atoms are kept fixed to determine U′(0…xi′…0,X3M) for calculating Lx1, Ly1, Lz1 (or Lx2, Ly2, Lz2). Clearly, it is an easy task for traditional ab initio algorithms and recently-developed DFT [45,46].…”

Section: Theoretical Methodsmentioning

confidence: 99%

“…The difference may have resulted from the limited computational precision of DFT. For calculating U0 and U′(0…xi′…0,X3M) in Equation (13) and (16), it is well known that the calculation results of DFT depend significantly on the specifically employed basis sets and exchange-correlation functionals of the electron density, for which the recent work [45,46] might provide better choices.…”

Section: Conditions For Silicene Growth On a Ag Substratementioning

confidence: 99%

A New Model to Predict Optimum Conditions for Growth of 2D Materials on a Substrate

et al. 2019

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Deposition of atoms or molecules on a solid surface is a flexible way to prepare various novel two-dimensional materials if the growth conditions, such as suitable surface and optimum temperature, could be predicted theoretically. However, prediction challenges modern theory of material design because the free energy criteria can hardly be applied to this issue due to the long-standing problem in statistical physics of the calculations of the free energy. Herein, we present an approach to the problem by the demonstrations of graphene and γ-graphyne on the surface of copper crystal, as well as silicene on a silver substrate. Compared with previous state-of-the-art algorithms for calculations of the free energy, our approach is capable of achieving computational precisions at least 10-times higher, which was confirmed by molecular dynamics simulations, and working at least four orders of magnitude faster, which enables us to obtain free energy based on ab initio calculations of the interaction potential instead of the empirical one. The approach was applied to predict the optimum conditions for silicene growth on different surfaces of solid silver based on density functional theory, and the results are in good agreement with previous experimental observations.

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“…Both semilocal and non-local functionals have achieved mixed successe in treating condensed phases and their ingredient atoms, molecules, and clusters and solids. Such functionals are either constraint-based and non-empirical [8][9][10][11][12][13][14][15][16][17][18] or semi-empirical 19,20 . With any significant ground-state advance, an obvious, important associated step is generalization to a non-interacting free energy functional F s .…”

mentioning

confidence: 99%

Towards accurate orbital-free simulations: A generalized gradient approximation for the noninteracting free energy density functional

2020

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For orbital-free ab initio molecular dynamics, especially on systems in extreme thermodynamic conditions, we provide the first pseudo-potential-adapted generalized gradient approximation (GGA) functional for the non-interacting free energy. This is achieved by systematic finite-temperature extension of our recent LKT ground state non-interacting kinetic energy GGA functional (Phys. Rev. B 98, 041111(R) (2018)). We test the performance of the new functional first via static lattice calculations on crystalline aluminum and silicon. Then we compare deuterium equation of state results against both path-integral Monte Carlo and conventional (orbital-dependent) Kohn-Sham results. The new functional, denoted LKTF, outperforms the previous best semi-local free energy functional, VT84F (Phys. Rev. B 88, 161108(R) (2013)), and provides modestly faster simulations. We also discuss subtleties of identification of kinetic and entropic contributions to non-interacting free-energy functionals obtained by extension from ground state orbital-free kinetic energy functionals.

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Nonlocal kinetic energy functional from the jellium-with-gap model: Applications to orbital-free density functional theory

Cited by 41 publications

References 126 publications

Semilocal kinetic energy functionals with parameters from neutral atoms

Semilocal kinetic energy functionals with parameters from neutral atoms

A New Model to Predict Optimum Conditions for Growth of 2D Materials on a Substrate

Towards accurate orbital-free simulations: A generalized gradient approximation for the noninteracting free energy density functional

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