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bandstructure.py
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bandstructure.py
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# coding: utf-8
# Copyright (c) Max-Planck-Institut für Eisenforschung GmbH - Computational Materials Design (CM) Department
# Distributed under the terms of "New BSD License", see the LICENSE file.
"""
This module is supposed to be common for both electronic and phonon band structures
"""
from __future__ import print_function
import numpy as np
from numpy import transpose as tr
from numpy.linalg import inv, norm
from pyiron_base import PyironObject
__author__ = "Joerg Neugebauer, Jan Janssen"
__copyright__ = (
"Copyright 2020, Max-Planck-Institut für Eisenforschung GmbH - "
"Computational Materials Design (CM) Department"
)
__version__ = "1.0"
__maintainer__ = "Jan Janssen"
__email__ = "janssen@mpie.de"
__status__ = "development"
__date__ = "Sep 1, 2017"
class BandPath(object):
def __init__(self, bs_obj, n_points=20):
self.bs_obj = bs_obj
self.translate_to_pylab = {"Gamma": r"$\Gamma$", "G'": r"$\Gamma^\prime$"}
self.q_points = list()
self.labels = bs_obj.path_dict.keys()
self.special_points = bs_obj.path_dict.values()
self.n_points = n_points
self.q_dist = np.zeros(n_points)
def _generate_points(self):
if not (self.bs_obj.structure is not None):
raise AssertionError()
spl_distances = list()
for i, sp in enumerate(self.special_points):
if i < len(self.special_points) - 1:
x1 = np.array(self.special_points[i + 1])
x2 = np.array(sp)
spl_distances.append(np.linalg.norm(x2 - x1))
class Bandstructure(PyironObject):
translate_to_pylab = {"Gamma": r"$\Gamma$", "G'": r"$\Gamma^\prime$"}
def __init__(self, structure=None, prec=1e-5):
self.prec = prec
self._structure = None
self.bmat = None
self.point_group = None
self.path_type = None
self.num_points = None
self.q_dist = None
self.q_points = None
self.q_ticks = None
self.q_labels = None
self.q_path = None
self.ew_list = None
self.ev_list = None
self._eigenvalues = None
self._path_dict = dict()
if structure:
self.structure = structure
@property
def structure(self):
return self._structure
@structure.setter
def structure(self, val):
self._structure = val
self.bmat = tr(inv(val.cell))
self.point_group = val.get_spacegroup(self.prec)["Number"]
self._assign_path()
@property
def path_dict(self):
return self._path_dict
@path_dict.setter
def path_dict(self, val):
self._path_dict = val
def _assign_path(self):
b1, b2, b3 = self.bmat
# print "B1",b1
# print "B2",b2
# print "B3",b3
point_group = self.point_group
special_points = {
"Gamma": [0, 0, 0],
"G'": b2,
"L": 0.5 * (b1 + b2 + b3),
"K": 1.0 / 8.0 * (3 * b1 + 6 * b2 + 3 * b3),
"U": 1.0 / 8.0 * (2 * b1 + 5 * b2 + 5 * b3),
"X": 0.5 * (b2 + b3),
"W": 0.25 * b1 + 0.75 * b2 + 0.5 * b3,
"X'": 0.5 * (b1 + 2 * b2 + b3),
# replace by correct nomenclature
"M": 0.5 * (b1 + b2),
"X1": 0.5 * b1,
"X2": 0.5 * b2,
}
if point_group == 225: # fcc
path_dict = {
"very_short": ["L", "Gamma", "X"],
"full": [
"Gamma",
"X",
"U",
"L",
"Gamma",
"K",
], # , "U", "W", "L", "K"],
"full_20": ["G", "X", "U", "Gamma", "L"],
"full_CM": ["G'", "X'", "K", "Gamma", "L"],
}
elif point_group == 229: # bcc
path_dict = {
"very_short": ["Gamma", "X"],
"full": ["Gamma", "X", "L", "W", "Gamma"],
}
elif point_group == 221: # sc
path_dict = {
"very_short": ["L", "Gamma", "X1"],
"full": ["Gamma", "X1", "X", "L", "Gamma"],
}
elif point_group == 129:
path_dict = {
"very_short": ["Gamma", "X1"],
"full": ["Gamma", "X1", "M", "X2", "Gamma"],
}
elif point_group == 123: # used here for 1d system
path_dict = {
"very_short": ["X2", "Gamma", "X1"],
"full": ["Gamma", "X1", "M", "X2", "Gamma"],
}
elif point_group == 166:
path_dict = {
"very_short": ["L", "Gamma", "X"],
# "full": ["Gamma", "X", "K", "Gamma", "L"],
# "full_20": ["Gamma", "X", "K", "Gamma", "L"]
"full": ["Gamma", "X", "Gamma", "L"],
"full_20": ["Gamma", "X", "Gamma", "L"],
}
elif point_group == 167:
path_dict = {
"very_short": ["L", "Gamma", "X"],
# "full": ["Gamma", "X", "K", "Gamma", "L"],
# "full_20": ["Gamma", "X", "K", "Gamma", "L"]
"full": ["Gamma", "X", "Gamma", "L"],
"full_20": ["Gamma", "X", "Gamma", "L"],
}
elif point_group == 186:
special_points = {
"Gamma": [0, 0, 0],
"A": 0.5 * b3,
"L": 0.5 * (b1 + b3),
"M": 0.5 * b1,
"K": (1.0 / 0.3) * (b1 + b2),
"H": (1.0 / 0.3) * (b1 + b2) + 0.5 * b3,
}
path_dict = {"full": ["A", "L", "M", "Gamma", "A"]}
else: # TODO: taking fcc path for testing reasons, change this later
path_dict = {
"very_short": ["L", "Gamma", "X"],
# "full": ["Gamma", "X", "K", "Gamma", "L"],
# "full_20": ["Gamma", "X", "K", "Gamma", "L"]
"full": ["Gamma", "X", "Gamma", "L"],
"full_20": ["Gamma", "X", "Gamma", "L"],
}
self.path_dict = path_dict
self.special_points = special_points
def get_pathes(self):
"""
provide dictionary with all predefined Bandstructure pathes for this structure
"""
return self.path_dict
def get_path(self, num_points=10, path_type="very_short"):
if path_type in self.path_dict.keys():
q_labels = self.path_dict[path_type]
else:
raise (
"path type "
+ path_type
+ " does not exist for point group "
+ str(self.point_group)
)
self.num_points = num_points
self.path_type = path_type
q_path = np.array([self.special_points[q_s] for q_s in q_labels])
self.q_path = q_path
# print "q_path: ", q_path
# get total length of q_path
q_length = 0.0
q_vec_list = []
for i, q in enumerate(q_path[1:]):
d_q = q - q_path[i]
q_vec_list.append(d_q)
q_length += norm(d_q)
delta_q = q_length / num_points
# get q-points on path
q_point_list = []
q_dist_list = []
q_dist_sum = 0.0
q_ticks = [] # indices where q is special point (for graphical output)
count = 0
for i, q_vec in enumerate(q_vec_list):
# print "q_vec: ", q_vec, q_path[i]
q_dist = norm(q_vec)
n_points = int(q_dist / delta_q + 0.5) + 1
delta_q_i = q_dist / n_points
delta = 1
if i == len(q_vec_list) - 1:
delta = 2
q_ticks.append(count)
for j in range(n_points + delta):
q_point = q_path[i] + j * q_vec / (n_points + 1)
q_point_list.append(q_point)
q_dist_sum += delta_q_i
q_dist_list.append(q_dist_sum)
if delta == 2 and j == n_points + 1:
q_ticks.append(count)
count += 1
self.q_dist = q_dist_list
self.q_points = q_point_list
self.q_ticks = q_ticks
self.q_labels = q_labels
self.ew_list = None
self.ev_list = []
return q_dist_list, q_point_list, [q_labels, q_ticks]
def set_eigenvalues(self, ew_list, ev_list=None):
if not len(ew_list) == len(self.q_points):
print("Failed")
raise (
"Number of eigenvalues inconsistent with q-path: "
+ str(len(ew_list))
+ " vs "
+ str(len(self.q_points))
)
self.ew_list = ew_list
self.ev_list = ev_list
def append_eigenvalues(self, ew, ev=None):
if self.ew_list is None:
self.ew_list = [ew]
if ev is not None:
self.ev_list = [ev]
else:
self.ew_list = np.append(self.ew_list, values=[ew], axis=0)
if ev is not None:
self.ev_list = np.append(self.ev_list, values=ev, axis=0)
def plot(self):
import pylab as plt
q_ticks_int = [self.q_dist[i] for i in self.q_ticks]
q_ticks_label = self.q_labels
for i, q in enumerate(q_ticks_label):
if q in self.translate_to_pylab:
q_ticks_label[i] = self.translate_to_pylab[q]
plt.plot(self.q_dist, self.ew_list)
plt.xticks(q_ticks_int, q_ticks_label)
for x in q_ticks_int:
plt.axvline(x, color="black")
return plt
def to_hdf(self, hdf=None, group_name=None):
if not group_name:
group_name = "bandstructure"
with hdf.open(group_name) as hdf5_band:
hdf5_band["path_type"] = self.path_type
hdf5_band["num_points"] = self.num_points
hdf5_band["q_dist"] = self.q_dist
hdf5_band["q_points"] = self.q_points
hdf5_band["q_ticks"] = self.q_ticks
hdf5_band["q_labels"] = self.q_labels
hdf5_band["ew"] = self.ew_list
def from_hdf(self, hdf=None, group_name=None):
if not group_name:
group_name = "bandstructure"
with hdf.open(group_name) as hdf5_band:
self.path_type = hdf5_band["path_type"]
self.num_points = hdf5_band["num_points"]
self.q_dist = hdf5_band["q_dist"]
self.q_points = hdf5_band["q_points"]
self.q_ticks = hdf5_band["q_ticks"]
self.q_labels = hdf5_band["q_labels"]
self.ew_list = hdf5_band["ew"]