Preparing a POTCAR

The POTCAR file is a mandatory input file that holds the pseudopotential for each element in the structure. The templates for each element can be downloaded from the VASP Portal. There are sometimes multiple templates for one element with subtle differences.

Step-by-step instructions

Step 1: Select the latest version of POTCAR files unless you need to use an older one to reproduce a result.

Step 2: Choose

• standard potentials for calculations depending mainly on occupied states, e.g., within density-functional theory, or
• GW variants if the calculation requires high accuracy for unoccupied states, i.e., for optical response and many-body perturbation theory.

Step 3: Select a POTCAR for a certain family of exchange-correlation (XC) functionals.

Tip: The standard choice is to use the GGA/PBE version based on LEXCH=PE.

All potentials are constructed based on solving the scalar relativistic Schrödinger equation for a reference system with a certain XC functional. One set is available for the LDA, and one for the GGA. The transferability to other XC functionals is seamless by specifying the XC tag in the INCAR. We recommend using the latest available potentials. Older versions are available to ensure reproducibility.

Step 4 (optional): Choose a POTCAR with a different atomic configuration or hard version.

Tip: The standard choice is to use the bold version in the list of PAW potentials.

See choosing pseudopotentials.

Important: Generally opt for the recommended POTCAR files, but test if the property of interest is sensitive to the choice of the pseudopotential. It may be possible to choose a computationally cheaper version or necessary to select a more demanding one.

Step 5: For a single element in the structure, you can copy the POTCAR to the working directory, e.g,

 cp ~/pot/Al/POTCAR .

For structures with multiple elements, the selected POTCAR files must be concatenated to create one POTCAR file containing all species present in the structure. Combine the potentials by entering, for instance,

 cat ~/pot/Al/POTCAR ~/pot/C/POTCAR ~/pot/H/POTCAR > POTCAR 

The order of the potentials must correspond to the order of the species in the POSCAR file.

Tip: If species names are given in the POSCAR, and the order does not match the order in the POTCAR, a warning is printed, but VASP will still run.

Recommendations and advice

Example for preparing a POTCAR for the Heusler alloy TiCo₂Si

In this example, we want to prepare a POTCAR for a PBE calculation of ferromagnetic TiCo₂Si. We are interested in the size of the magnetic moments.

The structure is defined by the following POSCAR:

TiCo2Si
 1.0
 -2.8580789844367893   -2.8580789844367889    0.0000000000000000
 -2.8580789844367889    0.0000000000000000   -2.8580789844367889
 -0.0000000000000005   -2.8580789844367889   -2.8580789844367889
Co Si Ti
 2  1  1
direct
  0.7500000000000000    0.7500000000000000    0.7500000000000000 Co
  0.2500000000000000    0.2500000000000000    0.2500000000000000 Co
  0.0000000000000000    0.0000000000000000    0.0000000000000000 Si
  0.4999999999999999    0.5000000000000000    0.5000000000000000 Ti

We will use the potpaw_PBE.64 potential set, and since we are interested in magnetic properties, we should use potentials with additional semicore-states in the valence. The Co_pv and Ti_sv potentials seem appropriate for the transition metals. We do not expect Si to become magnetic and are not interested in unoccupied states, so the Si potential is a good choice compared to the harder, computationally more demanding Si_GW or even Si_sv_GW.

On a UNIX machine, one can use the cat command to concatenate files together. One can redirect the output from stdout to a file using the > operator. The order in the POSCAR dictates the order in the POTCAR:

cat ~/potpaw_PBE.64/Co_pv/POTCAR ~/potpaw_PBE.64/Ti_sv/POTCAR ~/potpaw_PBE.64/Si/POTCAR > ~/scratch/TiCo2Si/POTCAR

Related tags and sections

Available potentials, POTCAR, Choosing pseudopotentials, Theory:Pseudopotential basics, Projector-augmented-wave formalism