Equilibrium volume of Si in the RPA: Difference between revisions

Revision as of 09:45, 3 April 2018

Calculation of the equilibrium lattice constant of Si in the RPA (ACFDT).

The workflow of RPA total energy calculations consists of five consecutive steps:

Step 1: a “standard” DFT groundstate calculation with a “dense” mesh of k-points.
Step 2: compute the Hartree-Fock energy using the orbitals of Step 1. Needs WAVECAR file from step 1.
Step 3: a “standard” DFT groundstate calculation with “coarse” mesh of k-points.
Step 4: obtain DFT “virtual” orbitals (empty states). Needs WAVECAR file from step 3.
Step 5: the RPA correlation energy (ACFDT) calculation. Needs WAVECAR and WAVEDER files from step 4.

In case of metallic systems there is an additional step between Steps 4 and 5, that is beyond the scope of this example.

All of the calculation steps are prepared in the script doall.sh.

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 {{Template:gw}}
-Description: calculation of the equilibrium lattice constant of Si in the RPA (ACFDT).
+== Task ==
+Calculation of the equilibrium lattice constant of Si in the RPA (ACFDT).
+== Calculation ==
+The workflow of RPA total energy calculations consists of five consecutive steps:
+*Step 1: a “standard” DFT groundstate calculation with a “dense” mesh of k-points.
+*Step 2: compute the Hartree-Fock energy using the orbitals of Step 1. Needs {{TAG|WAVECAR}} file from step 1.
+*Step 3: a “standard” DFT groundstate calculation with “coarse” mesh of k-points.
+*Step 4: obtain DFT “virtual” orbitals (empty states). Needs {{TAG|WAVECAR}} file from step 3.
+*Step 5: the RPA correlation energy (ACFDT) calculation. Needs {{TAG|WAVECAR}} and {{TAG|WAVEDER}} files from step 4.
+In case of metallic systems there is an additional step between Steps 4 and 5, that is beyond the
+scope of this example.
+All of the calculation steps are prepared in the script doall.sh.
+=== Step 1 ===
 ----
 == Used INCAR Tags ==