Bulk material: h-BN: Difference between revisions

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* Lattice constants: ''a'' = 4.716 [a.u.], ''c/a'' = 2.582
* Lattice constants: ''a'' = 4.716 [a.u.], ''c/a'' = 2.582
* Plane wave cutoff 40 Ry (1500 RL vectors in wavefunctions)
* Plane wave cutoff 40 Ry (1500 RL vectors in wavefunctions)
* SCF run: shifted ''6x6x6'' grid with 8 bands  
* SCF run: shifted ''6x6x2'' grid with 8 bands  
* Non-SCF run: unshifted ''6x6x2'' grid with 100 bands
* Non-SCF run: gamma-centred ''6x6x2'' grid with 100 bands


== DFT calculations ==
== DFT calculations ==
Line 27: Line 27:
First run the SCF calculation to generate the ground-state charge density, occupations, Fermi level, and so on:
First run the SCF calculation to generate the ground-state charge density, occupations, Fermi level, and so on:
  pw.x < hBN_scf.in > hBN_scf.out
  pw.x < hBN_scf.in > hBN_scf.out
The output reports 36 k-points. The valence band maximum is at 5.13eV.
The output reports 12 k-points. The valence band maximum is at 5.06eV.


Next run a non-SCF calculation to generate a set of Kohn-Sham eigenvalues and eigenvectors across a denser k-point mesh, for occupied and unoccupied states:  
Next run a non-SCF calculation to generate a set of Kohn-Sham eigenvalues and eigenvectors for both occupied and unoccupied states (100 bands):  
  pw.x < hBN_nscf.in > hBN_nscf.out
  pw.x < hBN_nscf.in > hBN_nscf.out
Here we use a ''6x6x2'' grid giving 14 k-points, but denser grids should be used for checking convergence of Yambo runs.
Note the presence of the following flags in the input file:
Note the presence of the following flags in the input file:
  wf_collect=.true.
  wf_collect=.true.

Revision as of 14:08, 23 March 2017

In this tutorial you will learn how to generate the Yambo SAVE folder for bulk hBN starting from a PWscf calculation.

Prerequisites

You will need:

  • PWSCF input files and pseudopotentials for hBN bulk (Download here)
  • pw.x executable, version 5.0 or later
  • p2y executable

System characteristics

Atomic structure of bulk hBN

Hexagonal boron nitride - hBN:

  • 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)
  • SCF run: shifted 6x6x2 grid with 8 bands
  • Non-SCF run: gamma-centred 6x6x2 grid with 100 bands

DFT calculations

Unpack the tarfile. It uses the same file structure as other yambo tutorials:

$ tar -xcvf hBN-bulk.tar
$ cd YAMBO_TUTORIALS/hBN/PWSCF
$ ls
Inputs		Pseudos		PostProcessing		References
hBN_scf.in	hBN_nscf.in     hBN_scf_plot_bands.in  hBN_nscf_plot_bands.in 

First run the SCF calculation to generate the ground-state charge density, occupations, Fermi level, and so on:

pw.x < hBN_scf.in > hBN_scf.out

The output reports 12 k-points. The valence band maximum is at 5.06eV.

Next run a non-SCF calculation to generate a set of Kohn-Sham eigenvalues and eigenvectors for both occupied and unoccupied states (100 bands):

pw.x < hBN_nscf.in > hBN_nscf.out

Here we use a 6x6x2 grid giving 14 k-points, but denser grids should be used for checking convergence of Yambo runs.

Note the presence of the following flags in the input file:

wf_collect=.true.
force_symmorphic=.true.

which are needed for generating the Yambo databases. 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 charge-density.dat gvectors.dat B.pz-vbc.UPF N.pz-vbc.UPF
K00001	K00002 .... 	K00035	K00036

Conversion to Yambo format

The PWscf bBN.save output is converted to the Yambo format using the p2y executable (pwscf to yambo), found in the yambo bin directory. Enter hBN.save and launch p2y:

$ cd hBN.save
$ p2y
...
<---> DBs path set to .
<---> Index file set to data-file.xml
<---> Header/K-points/Energies... done
...
<---> == DB1 (Gvecs and more) ...
<---> ... Database done
<---> == DB2 (wavefunctions)  ... done ==
<---> == DB3 (PseudoPotential) ... done ==
<--->  == P2Y completed ==

This output repeats some information about the system and generates a SAVE directory:

$ ls SAVE
ns.db1  ns.wf  ns.kb_pp_pwscf
ns.wf_fragments_1_1 ...
ns.kb_pp_pwscf_fragment_1 ...

These files, with an n prefix, indicate that they are in netCDF format, and thus not human readable. However, they are perfectly transferable across different architectures.

You are now ready to run Yambo. Check that the databases contain the information you expect:

$ yambo -D
[RD./SAVE//ns.db1]------------------------------------------
Bands                           : 100
K-points                        : 14
G-vectors             [RL space]:  8029
Components       [wavefunctions]: 1016
...
[RD./SAVE//ns.wf]-------------------------------------------
Fragmentation                    :yes
...
[RD./SAVE//ns.kb_pp_pwscf]----------------------------------
Fragmentation                    :yes
- S/N 006626 -------------------------- v.04.01.02 r.00000 -

In practice we suggest to move the SAVE into a new clean folder. In this tutorial however, we ask instead that you continue using a SAVE we prepared previously:

$ cd ../../YAMBO
$ ls
SAVE

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