KERNEL TRUNCATION/IDIMENSIONALITY: Difference between revisions

Revision as of 10:45, 17 March 2026

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

Description: 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. 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).

Mind:

If KERNEL_TRUNCATION/LTRUNCATE is switched off, all other KERNEL_TRUNCATION tags, i.e. KERNEL_TRUNCATION/IDIMENSIONALITY, KERNEL_TRUNCATION/LCOARSEN, and KERNEL_TRUNCATION/ISURFACE will be ignored.
This tag is only available as of VASP.6.5.0.

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
       IDIMENSIONALITY = 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 that is oriented along the z-axis

 KERNEL_TRUNCATION {
       LTRUNCATE      = T
       IDIMENSIONALITY = 2
       LCOARSEN       = T
       ISURFACE       = 3
 }

KERNEL_TRUNCATION/IDIMENSIONALITY = 3 (default)

The system is periodic in all dimensions, i.e. there is no influence of the Coulomb-kernel truncation on the resulting energies and forces.

References

[vijay:prb:2025-1] S. Vijay, M. Schlipf, H. Miranda, F. Karsai, M. Kaltak, M. Marsman, and G. Kresse, Efficient periodic density functional theory calculations of charged molecules and surfaces using Coulomb kernel truncation, Phys. Rev. B 112, 045409 (2025).

[rozzi:prb:2006-2] C. A. Rozzi, D. Varsano, A. Marini, E. K. Gross, A. J. Rubio, Phys. Rev. B 73, 20511 (2006).

[sohier:prb:2017-3] T. Sohier, M. Calandra, and F. Mauri, Phys. Rev. B 96, 75448 (2017).

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
 {{TAGDEF|KERNEL_TRUNCATION/IDIMENSIONALITY| 0 {{!}} 2 {{!}} 3 | 3}}
+{{DISPLAYTITLE:KERNEL_TRUNCATION/IDIMENSIONALITY}}
-Description: {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY}} specifies the boundary condition used to compute the hartree and ionic potential.
+Description: Specifies the boundary condition used to compute the hartree and ionic potential.
 ----
 If {{TAG|KERNEL_TRUNCATION/LTRUNCATE}} = T, {{TAG|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 {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY}} to either 0 or 2 uses the 0D and 2D truncated kernel respectively.{{cite|vijay:prb:2025}}{{cite|rozzi:prb:2006}}{{cite|sohier:prb:2017}}
 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).
@@ Line 30: / Line 30: @@
          ISURFACE       = 3
    }
+== {{TAG|KERNEL_TRUNCATION/IDIMENSIONALITY}} = 3 (default) ==
+The system is periodic in all dimensions, i.e. there is no influence of the Coulomb-kernel truncation on the resulting energies and forces.
 == Related tags and articles ==
@@ Line 40: / Line 44: @@
 == References ==
-[[Category:INCAR tag]][[Category:Electrostatics]]
+[[Category:INCAR tag]][[Category:Electrostatics]][[Category:2D materials]]