The fold2Bloch utility is designed to unfold the band structure of a supercell obtained with the Vienna Ab initio Simulation Package (VASP) and compute an effective band structure in a primitive representation. It facilitates interpretation of large-scale electronic structure calculations, where the Bloch character of electronic eigenstates is perturbed by a disorder (defects, alloy elements, etc). Reading of wavefunctions is adapted from the WaveTrans code.
- Oleg Rubel (McMaster University rubelo@mcmaster.ca)
- Michael Widom and Randall Feenstra (Carnegie Mellon University)
- Anton Bokhanchuk (Confederation College)
First clone the GitHub repository
$ git clone https://github.com/rubel75/fold2Bloch-VASP
The makefile
is set up for Intel Fortran compiler ifort
(gfortran
options are also available, but you need to uncomment several lines). To compile, simply execute
$ cd fold2Bloch-VASP; make
First, you need to perform the band structure calculation and generate WAVECAR file for the k-mesh of interest using standard VASP procedure (see VASP guidelines). (The following MATLAB script utils/fold.m
is designed to assist with preparing a folded string of k-points that will unfold on a desired k-path.) It is advised to increase the number of empty bands (NBANDS=... in INCAR file) by a factor of 1.2-2 beyond a VASP-proposed default value to get a reasonable description of higher energy states.
Once WAVECAR is ready, execute
/path/to/fold2Bloch WAVECAR "P11 P12 P13:P21 P22 P23:P31 P32 P33" [-ncl]
Options:
WAVECAR
-- name of the input VASP wavefunction file
"P11 P12 P13:P21 P22 P23:P31 P32 P33"
-- transformation matrix from primitive lattice vectors a_p
to supercell lattice vectors a_s
(same as in VESTA or the Bilbao Crystallographic Server):
a_s(i) = sum_j a_p(j)*P(j,i) i,j = 1, 2, 3
-ncl
-- optional switch that needs to be activated when the WAVECAR is produced by vasp_ncl code, which implies that the wavefunctions are spinors (default assumption is that WAVECAR comes from vasp_std or vasp_gam).
Output is written to WAVECAR_*.f2b
file(s). There is one output file for non-spin-polarized calculation and two files for the spin-polarized or spinor (vasp_ncl) calculations. Below is a sample of an output file.
New K-values (x, y, z) Eigenvalue (eV) Weight
0.000000 0.000000 0.000000 -22.019998 1.000000
0.000000 0.200000 0.000000 -22.019998 0.000000
0.000000 0.400000 0.000000 -22.019998 0.000000
0.000000 -0.400000 0.000000 -22.019998 0.000000
0.000000 -0.200000 0.000000 -22.019998 0.000000
0.200000 0.000000 0.000000 -22.019998 0.000000
...
The Matlab code utils/ubs_dots.m
or the octave code utils/ubs_bmp.m
are designed to assist with plotting the band structure and the Bloch weights. Please refer to its input section for description of user input variables. Each plotting tool has its own pros/cons. Below is a sample of the MATLAB plot for the unfolded band structure of a dilute GaP:N alloy. It is followed by a different style plot of a dynamic band structure in a perovskite lattice generated using Octave utils/ubs_bmp.m
and gnuplot utils/f2b-band-structure.plt
from Phys. Rev. Materials 2, 114604 (2018).
If you find the results useful and publishable, we will appreciate citing the following papers:
- O. Rubel, A. Bokhanchuk, S. J. Ahmed, and E. Assmann "Unfolding the band structure of disordered solids: from bound states to high-mobility Kane fermions", Phys. Rev. B 90, 115202 (2014).
- L.-W. Wang, L. Bellaiche, S.-H. Wei, and A. Zunger "Majority representation of alloy electronic states", Phys. Rev. Lett. 80, 4725 (1998).