KERNEL TRUNCATION/IDIMENSIONALITY: Difference between revisions
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== Related tags and articles == | == Related tags and articles == | ||
{{TAG| | {{TAG|KERNEL_TRUNCATION/LTRUNCATE}}, | ||
{{TAG| | {{TAG|KERNEL_TRUNCATION/LCOARSEN}}, | ||
{{TAG| | {{TAG|KERNEL_TRUNCATION/ISURFACE}} | ||
== References == | == References == |
Revision as of 09:34, 18 December 2024
KERNEL_TRUNCATION/IDIMENSIONALITY = 0 | 2 | 3
Default: KERNEL_TRUNCATION/IDIMENSIONALITY = 3
Description: KERNEL_TRUNCATION/IDIMENSIONALITY specifies the boundary condition used to compute the hartree and ionic potential
If KERNEL_TRUNCATION/LTRUNCATE = T, KERNEL_TRUNCATION/IDIMENSIONALITY determines the boundary condition that is used to compute the local potential. The default value of 3 implies that the system is periodic in all dimensions, i.e. there is no influence of kernel truncation on the resulting energies and forces. Setting KERNEL_TRUNCATION/IDIMENSIONALITY to either 0 or 2 uses the 0D and 2D truncated kernel respectively.[1][2][3] These kernels create 0D (i.e. no periodic interactions, as is the case of molecules) and 2D (i.e. periodic interactions only in two dimensions, as in the case for surfaces).
KERNEL_TRUNCATION/IDIMENSIONALITY = 0
Consider using the option when computing energies and forces of atoms and molecules. Recommended INCAR tags to be used with option are
KERNEL_TRUNCATION { LTRUNCATE = T IDIMENIONALITY = 0 LCOARSEN = T }
KERNEL_TRUNCATION/IDIMENSIONALITY = 2
Use this option when computing the energies and forces of 2D and quasi-2D systems, such as 2D materials and surfaces. We suggest setting the following INCAR tags for a surface which is oriented along the z-axis
KERNEL_TRUNCATION { LTRUNCATE = T IDIMENIONALITY = 2 LCOARSEN = T ISURFACE = 3 }
Related tags and articles
KERNEL_TRUNCATION/LTRUNCATE, KERNEL_TRUNCATION/LCOARSEN, KERNEL_TRUNCATION/ISURFACE