LASPH: Difference between revisions
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{{TAGDEF|LASPH|.TRUE. {{!}} .FALSE.|.FALSE.}} | {{TAGDEF|LASPH|.TRUE. {{!}} .FALSE.|.FALSE.}} | ||
Description: include non-spherical contributions to the gradient | Description: include non-spherical contributions related to the gradient of the density in the PAW spheres. | ||
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Usually VASP calculates only the spherical contribution to the gradient corrections inside the PAW spheres (non- | Usually VASP calculates only the spherical contribution to the gradient corrections inside the PAW spheres (non-spherical contributions for the LDA part of the potential and the Hartree potential are always included). | ||
For {{TAG|LASPH}} = .TRUE., non-spherical contributions from the gradient corrections inside the PAW spheres will be included as well. For VASP.4.6, these contributions are only included in the total energy, after self-consistency has been reached disregarding the aspherical contributions in the gradient corrections. | For {{TAG|LASPH}} = .TRUE., non-spherical contributions from the gradient corrections inside the PAW spheres will be included as well. For VASP.4.6, these contributions are only included in the total energy, after self-consistency has been reached disregarding the aspherical contributions in the gradient corrections. | ||
For VASP.5.X the aspherical contributions are properly accounted for in the Kohn-Sham potential as well. This is essential for accurate total energies and band structure calculations for ''f''-elements (e.g. ceria), all 3''d''-elements (transition metal oxides), and magnetic atoms in the 2nd row (B-F atom), in particular if | For VASP.5.X the aspherical contributions are properly accounted for in the Kohn-Sham potential as well, if | ||
{{TAG|LASPH}} = .TRUE. is set. This is essential for accurate total energies and band structure calculations for ''f''-elements (e.g. ceria), all 3''d''-elements (transition metal oxides), and magnetic atoms in the 2nd row (B-F atom), in particular if DFT+U or hybrid functionals, meta-GGAs, or vdW-DFT are used, since these functionals often result in aspherical charge densities. | |||
== Related | == Related tags and articles == | ||
{{TAG|LMAXPAW}}, | {{TAG|LMAXPAW}}, | ||
{{TAG|LMAXTAU}}, | {{TAG|LMAXTAU}}, | ||
{{TAG|LMIXTAU}} | {{TAG|LMIXTAU}} | ||
{{sc|LASPH|Examples|Examples that use this tag}} | |||
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[[Category:INCAR]] | [[Category:INCAR tag]][[Category:Exchange-correlation functionals]][[Category:meta-GGA]] |
Latest revision as of 14:26, 8 April 2022
LASPH = .TRUE. | .FALSE.
Default: LASPH = .FALSE.
Description: include non-spherical contributions related to the gradient of the density in the PAW spheres.
Usually VASP calculates only the spherical contribution to the gradient corrections inside the PAW spheres (non-spherical contributions for the LDA part of the potential and the Hartree potential are always included).
For LASPH = .TRUE., non-spherical contributions from the gradient corrections inside the PAW spheres will be included as well. For VASP.4.6, these contributions are only included in the total energy, after self-consistency has been reached disregarding the aspherical contributions in the gradient corrections.
For VASP.5.X the aspherical contributions are properly accounted for in the Kohn-Sham potential as well, if LASPH = .TRUE. is set. This is essential for accurate total energies and band structure calculations for f-elements (e.g. ceria), all 3d-elements (transition metal oxides), and magnetic atoms in the 2nd row (B-F atom), in particular if DFT+U or hybrid functionals, meta-GGAs, or vdW-DFT are used, since these functionals often result in aspherical charge densities.