Band structure of Ni: Difference between revisions

Latest revision as of 12:30, 16 November 2014

Input file

ni_lcao.py

from gpaw import GPAW, FermiDirac
from ase import Atoms
from ase.io import read, write
from gpaw import GPAW, PoissonSolver, MixerSum
from ase.structure import bulk

# -------------------------------------------------------------
# Bulk configuration
# -------------------------------------------------------------

a = 3.5249 
atoms = bulk('Ni', 'fcc', a=a)
atoms.center()

write('system.traj', atoms)

for a in atoms:
    if a.symbol == 'Ni':
        a.magmom = 0.6

# Make self-consistent calculation and save results
calc = GPAW(h=0.18,
            mode='lcao',
            xc='PBE',
            basis='dzp',
            kpts=(8,8,8),
            occupations=FermiDirac(width=0.05, maxiter=2000),
            mixer=MixerSum(beta=0.010, nmaxold=8, weight=100.0),
            poissonsolver=PoissonSolver(eps=1e-12),
            txt='band_sc.txt')

atoms.set_calculator(calc)
atoms.get_potential_energy()
calc.write('band_sc.gpw')


# Calculate band structure along Gamma-X 

from ase.dft.kpoints import ibz_points, get_bandpath
points = ibz_points['fcc']
G = points['Gamma']
X = points['X']
kpts, x, X = get_bandpath([G, X], atoms.cell, 80)

calc = GPAW('band_sc.gpw',
            mode='lcao',
            xc='PBE',
            basis='dzp',
            kpts=kpts,
            txt='band_harris.txt',
            fixdensity=True,
            parallel={'domain': 1},
            usesymm=None,
            convergence={'bands': 'all'})

if calc.input_parameters['mode'] == 'lcao':
    calc.scf.reset()

calc.get_potential_energy()
ef = calc.get_fermi_level()
calc.write('band_harris.gpw')

# Extract eigenenergies into a file for plotting with some external package

import numpy as np

calc = GPAW('band_harris', txt=None)
eps_skn = np.array([[calc.get_eigenvalues(k,s)
                     for k in range(80)]
                    for s in range(2)]) - ef

f = open('bands.dat', 'w')
for n in range(10):
    for k in range(80):
        print >>f, k, eps_skn[0, k, n], eps_skn[1, k, n]
    print >>f

Run job in parallel

Run band structure calculations in parallel using 8 cores on ulam:

 mpirun -np 8 gpaw-python_openmpi ni_lcao.py

Plot the results

Reproduce the figure below using gnuplot or transfer data to your Windows PC via sftp and use Origin:

 
gnuplot> plot "bands.dat" using 1:2 with lines title "Spin up", "bands.dat" using 1:3 with lines title "Spin down"

FIG. 1: Electronic band structure of fcc-Ni.

@@ Line 1: / Line 1: @@
-==Input files ==
+==Input file ==
-* Save two files below as *.py files.
+*ni_lcao.py
-===band.py===
 <pre>
 from gpaw import GPAW, FermiDirac
 from ase import Atoms
@@ Line 66: / Line 63: @@
 calc.get_potential_energy()
+ef = calc.get_fermi_level()
 calc.write('band_harris.gpw')
-</pre>
+# Extract eigenenergies into a file for plotting with some external package
-===find_band_as_dat.py===
+import numpy as np
-<pre>
-from ase.lattice import bulk
-from gpaw import GPAW
 calc = GPAW('band_harris', txt=None)
-import numpy as np
 eps_skn = np.array([[calc.get_eigenvalues(k,s)
                       for k in range(80)]
-                     for s in range(2)]) - 10.75103
+                     for s in range(2)]) - ef
+f = open('bands.dat', 'w')
 for n in range(10):
      for k in range(80):
-         print k, eps_skn[0, k, n], eps_skn[1, k, n]
+         print >>f, k, eps_skn[0, k, n], eps_skn[1, k, n]
-     print
+     print >>f
-</pre>
-==Job submission script==
-*Save the following into a file '''jobscript''' within your working directory
-<pre>
-#$ -N band
-#$ -o out.log
-#$ -e band.err
-#$ -pe openmpi 16
-#$ -l h_rt=3:00:00
-#
-source /opt/shared/valet/docs/valet.sh
-vpkg_rollback all
-vpkg_require numpy/1.6.1-2.7
-vpkg_require mkl/10.3.8-64bit
-vpkg_require openmpi/1.6.1-intel64
-#
-export PYTHONPATH=/lustre/scratch/ksaha/gpaw/ase:$PYTHONPATH
-export PATH=/lustre/scratch/ksaha/gpaw/ase/tools:$PATH
-export GPAW_SETUP_PATH=/lustre/scratch/ksaha/gpaw/gpaw-setups-0.8.7929
-export PYTHONPATH=/lustre/scratch/ksaha/gpaw/gpaw:${PYTHONPATH}
-export PYTHONPATH=/lustre/scratch/ksaha/gpaw/gpaw/build/lib.linux-x86_64-2.7:${PYTHONPATH}
-export PATH=/lustre/scratch/ksaha/gpaw/gpaw/build/bin.linux-x86_64-2.7:/lustre/scratch/ksaha/gpaw/gpaw/tools:${PATH}
-#
-#
-cd /home/1076/FCC-Ni_bandstructure/Wiki
-#
-mpirun /lustre/scratch/ksaha/gpaw/gpaw/build/bin.linux-x86_64-2.7/gpaw-python band.py
-#mpirun /lustre/scratch/ksaha/gpaw/gpaw/build/bin.linux-x86_64-2.7/gpaw-python find_band_as_dat.py
 </pre>
-==Running the job script==
+==Run job in parallel==
-*To run '''band.py''' execute:
- qsub jobscript
-*To run '''find_band_as_dat.py''' execute:
-:'''1.''' modify the 4th line of the jobscript "#$ -pe openmpi 16" to "#$ -pe openmpi 1" -- this means we will be running in a single core.
-:'''2.''' comment the second last line and uncomment the very last line of the jobscript
-:'''3.''' then submit job: qsub jobscript
-:'''4.''' bands should be generated into "out.log" file
+* Run band structure calculations in parallel using 8 cores on ulam:
+  mpirun -np 8 gpaw-python_openmpi ni_lcao.py
-==Test results==
+==Plot the results==
-* Once you successfully finish running both jobs, you should be able to reproduce this figure (using [http://www.gnuplot.info/ gnuplot] on Mills or transfer data to your Windows PC via sftp and use Origin):
+* Reproduce the figure below using [http://www.gnuplot.info/ gnuplot] or transfer data to your Windows PC via sftp and use Origin:
 <pre>
-gnuplot> plot "result.dat" using 1:2 with lines title "Spin up", "result.dat" using 1:3 with lines title "Spin down"
+gnuplot> plot "bands.dat" using 1:2 with lines title "Spin up", "bands.dat" using 1:3 with lines title "Spin down"
 </pre>

Band structure of Ni: Difference between revisions

Latest revision as of 12:30, 16 November 2014

Input file

Run job in parallel

Plot the results

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