ESF SPLINES: Difference between revisions
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{{NB|tip|This method works for metals and insulators.}} | {{NB|tip|This method works for metals and insulators.}} | ||
{{NB|warning|Remove {{FILE|WAVEDER}} before running the job and avoid setting {{TAG|LOPTICS}}.}} | {{NB|warning|Remove {{FILE|WAVEDER}} before running the job and avoid setting {{TAG|LOPTICS}}.}} | ||
{{NB|mind|available as of VASP.6.4.0}} | |||
== Related tags and articles == | == Related tags and articles == |
Revision as of 06:53, 12 June 2024
ESF_SPLINES = .FALSE. | .TRUE.
Default: ESF_SPLINES = .FALSE.
Description: ESF_SPLINES selects k-point interpolation in ACFDT(R) calculations using tri-cubic splines.
Interpolates the electronic structure factor in ACFDT/RPA calculations using tri-cubic splines to accelerate k-point convergence of the RPA correlation energy. This feature follows the same idea as in coupled cluster calculations.[1]
To this end, the electronic structure factor in the RPA
is evaluated on the k-point grid defined in KPOINTS and the correlation energy (as its trace) is stored.[2] To obtain the correlation energy on a finer k-point grid, more q-points are added using tri-cubic spline interpolation and the resulting energy is compared to the previous correlation energy. This procedure is repeated ESF_NINTER times until the difference in energy between the interpolation steps is less than ESF_CONV. The default settings of ESF_NINTER and ESF_CONV typically yield similar k-point convergence compared to the k-p perturbation theory approach, where the limit is stored to WAVECAR in a preceding DFT calculation using LOPTICS=T.
Tip: This method works for metals and insulators. |
Warning: Remove WAVEDER before running the job and avoid setting LOPTICS. |
Mind: available as of VASP.6.4.0 |