Bulk material: h-BN
Prerequisites
You will need:
- PWSCF input files and pseudopotentials for hBN bulk (Download here)
pw.x
executable, version 5.0 or laterp2y
executable
Material properties
Material properties:
- HCP lattice, ABAB stacking
- Four atoms per cell, B and N (16 electrons, )
- Lattice constants: a = 4.716 [a.u.], c/a = 2.582
- Plane wave cutoff 40 Ry (1500 RL vectors in wavefunctions)
Unpack the TARFILE:
$ tar -xcvf hBN-bulk.tar $ cd hBN/PWSCF $ ls hbn_bands.in hbn_nscf.in hbn_scf.in hbn_scf_b.in REFERENCES
DFT calculations
First run the SCF calculation in the usual manner, e.g.
pw.x < hBN_scf.in > hBN_scf.out
and then the non-SCF calculation to generate a set of Kohn-Sham eigenvalues and eigenvectors across a denser k-point mesh and for occupied and unoccupied states:
pw.x < hBN_nscf.in > hBN_nscf.out
Note the presence of the following flags in the input file:
wf_collect=.true. force_symmorphic=.true.
which are needed for the next step. Full explanations of these variables are given on the quantum-ESPRESSO input variables page. After these two runs, you should have a hBN.save
directory:
$ ls hBN.save data-file.xml
Conversion to Yambo format
PWscf output is converted to the Yambo format using the p2y
(pwscf to yambo), found in the yambo bin
directory.
Enter the hbn.save
directory and launch p2y
:
$ cd hBN.save $ p2y [output]
The code reports some information about the system and generates a SAVE
directory:
$ ls SAVE HB,in etc $ ls SAVE ns.db1 ns.wf ns.kb_pp_pwscf ns.wf_fragments_1_1 ... ns.kb_pp_pwscf_fragment_1 ...
Finally, let's move the SAVE directory into a new clean folder:
mv SAVE ../YAMBO/
Advanced users
p2y
accepts several command line options:
$ p2y -H
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