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{{Template:Input and Output - Tutorial}}
{{Template:Input and Output - Tutorial}}


VASP basically gives 4 input files for standard production runs:
VASP basically needs 4 input files for standard production runs:


== {{TAG|INCAR}} ==
== {{TAG|INCAR}} ==
*The {{TAG|INCAR}} file gives the input paramteres which "steer" the calculation.
*The {{TAG|INCAR}} file holds the input parameters which "steer" the calculation.
*The default values set by VASP itself are a clever choice to do standard calculations.
*The default values set by VASP itself are a clever choice to do standard calculations.
*These standard settings can be modified to specify:
*These standard settings can be modified to specify:
**What do you want to do? (scf calculation, DOS, dielectric properties ...)
**What do you want to do? (scf calculation, DOS, dielectric properties ...)
**You can give parameters to fulfil your requirements concerning required precision, requested convergence, calculation time ...
**You can give parameters to fulfill your requirements concerning required precision, requested convergence, calculation time ...


== {{TAG|POSCAR}} ==
== {{TAG|POSCAR}} ==

Revision as of 17:51, 24 June 2019

VASP basically needs 4 input files for standard production runs:

INCAR

  • The INCAR file holds the input parameters which "steer" the calculation.
  • The default values set by VASP itself are a clever choice to do standard calculations.
  • These standard settings can be modified to specify:
    • What do you want to do? (scf calculation, DOS, dielectric properties ...)
    • You can give parameters to fulfill your requirements concerning required precision, requested convergence, calculation time ...

POSCAR

  • A sample POSCAR file can look as the following:
fcc:  Ni
3.53
0.5 0.5 0.0
0.0 0.5 0.5
0.5 0.0 0.5
Ni
1
Selective Dyn
Cartesian
0 0 0 ( T T T)
  • The description of each line is given as follows:
    • 1: Header (comment).
    • 2: Overall scaling constant.
    • 3-6: Bravais matrix.
    • 4: Name(s) of the atom(s).
    • 5: Number of the atoms (of each atom type).
    • 6: (optional: selective dynamics).
    • 7: Specifies which coordinate system is used (carthesian or direct).
    • 8-x: Positions of the atoms.

KPOINTS

  • A sample KPOINTS file can look like the following:
Automatic mesh
0
G (M)
4 4 4
0.  0.  0.
  • The description of each line is given as follows:
    • 1: Header (comment).
    • 2: Specifies the k mesh generation type. : automatic generation scheme.
    • 3: -centered (Monkhorst-Pack) grid.
    • 4: Number of subdivisions in each direction.
    • 5: Optional shift of the mesh.

POTCAR

  • The POTCAR file contains the relevant information concerning the pseudo potentials that are necessary to run the calculation:
    • Data that was required for generating the pseudo potentials.
    • Number of valence electrons.
    • Atomic mass.
    • Energy cut-off.
  • If the cell contains different atoms, the atomic POTCAR files have to be concatenated, in the same order as the atoms are given in the POSCAR file.
  • Different XC-types must not be mixed.

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