Optimizing density-functional simulations for two-dimensional metals
Abidi, K. R., & Koskinen, P. (2022). Optimizing density-functional simulations for two-dimensional metals. Physical review materials, 6(12), Article 124004. https://doi.org/10.1103/physrevmaterials.6.124004
Julkaistu sarjassa
Physical review materialsPäivämäärä
2022Oppiaine
FysiikkaOpettajien koulutuksen tutkimus (opetus, oppiminen, opettajuus, oppimispolut, koulutus)Kiihdytinfysiikka ja subatomäärinen fysiikkaNanoscience CenterPhysicsTeacher education research (teaching, learning, teacher, learning paths, education)Accelerator and Subatomic PhysicsNanoscience CenterTekijänoikeudet
©2022 American Physical Society
Unlike covalent two-dimensional (2D) materials like graphene, 2D metals have nonlayered structures due to their nondirectional, metallic bonding. While experiments on 2D metals are still scarce and challenging, density-functional theory (DFT) provides an ideal approach to predict their basic properties and assist in their design. However, DFT methods have rarely been benchmarked against metallic bonding at low dimensions. Therefore, to identify optimal DFT attributes for a desired accuracy, we systematically benchmark exchange-correlation functionals from LDA to hybrids and basis sets from plane waves to local basis with different pseudopotentials. With 1D chain, 2D honeycomb, 2D square, 2D hexagonal, and 3D bulk metallic systems, we compare the DFT attributes using bond lengths, cohesive energies, elastic constants, densities of states, and computational costs. Although today most DFT studies on 2D metals use plane waves, our comparisons reveal that local basis with often-used Perdew-Burke-Ernzerhof exchange correlation is quite sufficient for most purposes, while plane waves and hybrid functionals bring limited improvement compared to the greatly increased computational cost. These results ease the demands for generating DFT data for better interaction with experiments and for data-driven discoveries of 2D metals incorporating machine learning algorithms.
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American Physical Society (APS)ISSN Hae Julkaisufoorumista
2476-0455Julkaisu tutkimustietojärjestelmässä
https://converis.jyu.fi/converis/portal/detail/Publication/164923110
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