KERNEL TRUNCATION/IDIMENSIONALITY: Difference between revisions

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If {{TAG|KERNEL_TRUNCATION/LTRUNCATE_KERNEL}} = T, {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF}} 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.
If {{TAG|KERNEL_TRUNCATION/LTRUNCATE_KERNEL}} = T, {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF}} 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 {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF}} to either 0 or 2 uses the 0D and 2D truncated kernel respectively [cite].
These kernels effectively 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).

Revision as of 09:45, 15 October 2024

KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF = 0 | 2 | 3
Default: KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF = 3 

Description: KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF specifies the boundary condition used to compute the hartree and ionic potential


If KERNEL_TRUNCATION/LTRUNCATE_KERNEL = T, KERNEL_TRUNCATION/IDIMENSIONALITY_CUTOFF 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_CUTOFF to either 0 or 2 uses the 0D and 2D truncated kernel respectively [cite]. These kernels effectively 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).