Subband structure of carbon nanotubes: Difference between revisions

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from ase.io import read, write
from ase.io import read, write
from gpaw import GPAW, PoissonSolver, Mixer
from gpaw import GPAW, PoissonSolver, Mixer
from ase.structure import nanotube
from ase.lattice import nanotube


# -------------------------------------------------------------
# -------------------------------------------------------------

Revision as of 14:43, 9 November 2014

Tools

Metallic (7,0) CNT using LCAO

  • cnt7-0_lcao.py:
from gpaw import GPAW, FermiDirac
from ase import Atoms
from ase.io import read, write
from gpaw import GPAW, PoissonSolver, Mixer
from ase.lattice import nanotube

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

cnt = nanotube(7, 0, length=1, bond=1.4, symbol='C')

cnt.center()
write('cnt.traj', cnt)


# Make self-consistent calculation and save results
calc = GPAW(h=0.18,
            mode='lcao',
            xc='PBE',
            basis='szp(dzp)',
            kpts=(1,1,9),
            occupations=FermiDirac(width=0.05, maxiter=2000),
            mixer=Mixer(beta=0.010, nmaxold=8, weight=100.0),
            poissonsolver=PoissonSolver(eps=1e-12),
            txt='band_sc.txt')

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


# Calculate band structure along Gamma-X 
from ase.dft.kpoints import ibz_points, get_bandpath
G = (0, 0, 0)
X = (0, 0, 0.5)
kpts, x, X = get_bandpath([G, X], cnt.cell, 60)

calc = GPAW('band_sc.gpw',
            mode='lcao',
            xc='PBE',
            basis='szp(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')

calc = GPAW('band_harris', txt=None)
import numpy as np

eps_skn = np.array([[calc.get_eigenvalues(k,s)
                     for k in range(60)]
                    for s in range(1)]) - ef



# Write the results to a file e.g. for plotting with gnuplot
f = open('bands.dat', 'w')
for n in range(66):
    for k in range(60):
        print >>f, k, eps_skn[0, k, n]
    print >>f

Semiconducting (7,7) CNT using LCAO

  • cnt7-7_lcao.py:
from gpaw import GPAW, FermiDirac
from ase import Atoms
from ase.io import read, write
from gpaw import GPAW, PoissonSolver, Mixer
from ase.structure import nanotube

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

cnt = nanotube(7, 7, length=1, bond=1.4, symbol='C')

cnt.center()
write('cnt.traj', cnt)


# Make self-consistent calculation and save results
calc = GPAW(h=0.18,
            mode='lcao',
            xc='PBE',
            basis='szp(dzp)',
            kpts=(1,1,9),
            occupations=FermiDirac(width=0.05, maxiter=2000),
            mixer=Mixer(beta=0.010, nmaxold=8, weight=100.0),
            poissonsolver=PoissonSolver(eps=1e-12),
            txt='band_sc.txt')

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


# Calculate band structure along Gamma-X 
from ase.dft.kpoints import ibz_points, get_bandpath
G = (0, 0, 0)
X = (0, 0, 0.5)
kpts, x, X = get_bandpath([G, X], cnt.cell, 60)

calc = GPAW('band_sc.gpw',
            mode='lcao',
            xc='PBE',
            basis='szp(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')

calc = GPAW('band_harris', txt=None)
import numpy as np
eps_skn = np.array([[calc.get_eigenvalues(k,s)
                     for k in range(60)]
                    for s in range(1)]) - ef

# Write the results to a file e.g. for plotting with gnuplot
f = open('bands.dat', 'w')
for n in range(66):
    for k in range(60):
        print >>f, k, eps_skn[0, k, n]
    print >>f