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"""empirical parameter calculator, includes calculation functions for 14 values:
'Enthalpy(kJ/mol)', 'std_enthalpy(kJ/mol)', 'average_atomic_radius', 'Delta(%)', 'Omega', 'Entropy(J/K*mol)', 'Tm(K)',
'std_Tm (%)', 'X', 'std_X(%)', 'VEC', 'std_VEC', 'Density(g/com^3)', 'Price(USD/kg)'
written by Will Nash and Zhipeng Li
version 2.1.1"""
import itertools
import numpy as np
from pip._internal import main
# main(['install', 'joblib'])
main(['install', 'matminer'])
import matminer.utils.data as mm_data
# the market price for most chemical elements, these data are retrieved from
# http://www.leonland.de/elements_by_price/en/list
price_dic = {
"Ag": 462, "Al": 1.91, "Au": 38189, "B": 2386, "Be": 831.6, "Bi": 10.34, "C": 24, "Ca": 5.93, "Cd": 1.98, "Ce": 7,
"Co": 59.5, "Cr": 7.64, "Cu": 5.9, "Dy": 350, "Er": 95, "Fe": 0.08, "Gd": 55, "Ge": 1833, "Hf": 1414, "Ho": 1400,
"In": 341.6, "Ir": 31186, "La": 7, "Li": 115.7, "Lu": 6269, "Mg": 2.26, "Mn": 2.06, "Mo": 16, "Nb": 42, "Nd": 60,
"Ni": 9.19, "Os": 12860, "P": 300, "Pb": 2.29, "Pd": 34401, "Pr": 85, "Pt": 26492, "Re": 1635, "Rh": 76840,
"Ru": 14720, "Sb": 7.05, "Sc": 15000, "Si": 1.91, "Sm": 14.35, "Sn": 20, "Sr": 5.4, "Ta": 238, "Tb": 550,
"Ti": 3.77, "Tm": 6200, "V": 22.6, "W": 25.52, "Y": 35, "Yb": 1600, "Zn": 2.83, "Zr": 23.14, "H": 23.64,
"He": 40.39, "N": 2.77, "O": 0.64, "F": 1900, "Ne": 629.9, "Na": 3.04, "S": 0.1, "Cl": 1.5, "Ar": 2.56, "K": 13.02,
"Ga": 278.2, "As": 1.74, "Se": 30.37, "Br": 4.4, "Kr": 1.4, "Rb": 14720, "Te": 55.68, "I": 28.00,
"Xe": 9.2, "Cs": 73400, "Ba": 550, "Eu": 258, "Hg": 38.44, "Tl": 7400, "Th": 176, "U": 57.76,
}
class EmpiricalParams(object):
"""functions for returning the empirical parameters of alloy compositions where element list is a list of pymatgen
Elements that are in the alloy, and mol_ratio is their respective mole ratios """
def __init__(self, element_list, mol_ratio=None):
self.element_list = element_list
if mol_ratio is None: # assume that mol_ratio is evenly distributed amongst elements
mol_ratio = [1 / len(element_list)] * len(element_list)
self.mol_ratio = np.divide(mol_ratio, np.sum(mol_ratio))
self.a = self.mean_atomic_radius()
self.delta = self.atomic_size_difference()
self.Tm = self.average_melting_point()
self.mix_entropy = self.entropy_mixing()
self.mix_enthalpy = self.enthalpy_mixing()
self.omega = self.calc_omega()
self.x = self.mean_electronegativity()
self.std_x = self.std_electronegativity()
self.vec = self.average_vec()
self.density = self.calc_density()
self.price = self.calc_price()
# self.k = self.mean_bulk_modulus()
# self.std_k = self.std_bulk_modulus()
self.std_enthalpy = self.std_enthalpy_mixing()
self.std_Tm = self.std_melting_point()
self.vec_std = self.std_vec()
'''
2. average atomic radius
'''
def mean_atomic_radius(self):
"""function to return the mean atomic size radius 平均原子尺寸半径 (a) of the alloy"""
radii = []
for i in range(len(self.element_list)):
radii.append(self.element_list[i].atomic_radius)
avg_radii = np.dot(radii, self.mol_ratio)
return avg_radii
'''
3. atomic size difference
'''
def atomic_size_difference(self):
"""function to return the atomic size difference 原子半径差比率 (delta) of the alloy"""
delta = 0
radii = []
for i in range(len(self.element_list)):
radii.append(self.element_list[i].atomic_radius)
for j in range(len(self.element_list)):
delta += self.mol_ratio[j] * np.square((1 - np.divide(radii[j], self.a)))
return np.sqrt(delta)
'''
6. average melting point
'''
def average_melting_point(self):
"""function to return the average melting point 熔点的均值 (Tm) of the alloy"""
Tm = 0
for i in range(len(self.element_list)):
Tm += self.mol_ratio[i] * self.element_list[i].melting_point
return Tm
'''
7. standard melting point
'''
def std_melting_point(self):
"""function to return the standard deviation (in percentage) of melting points 熔点的标准偏差 (sigma_t) of the alloy"""
sigma_t = 0
T = []
for i in range(len(self.element_list)):
T.append(self.element_list[i].melting_point)
for j in range(len(self.element_list)):
sigma_t += self.mol_ratio[j] * np.square((1 - np.divide(T[j], self.Tm)))
return np.sqrt(sigma_t)
'''
1. entropy of mixing
'''
def entropy_mixing(self):
"""function to return entropy of mixing 混合熵 for alloy elements based on Boltzmann's hypothesis"""
entropy = 0
for i in range(len(self.mol_ratio)):
if self.mol_ratio[i] > 0:
entropy += self.mol_ratio[i] * np.log(self.mol_ratio[i])
return -8.31446261815324 * entropy
'''
4. enthalpy of mixing
'''
def enthalpy_mixing(self):
"""function to return the sum enthalpy of mixing 混合焓和 of an alloy system based on binary mixtures and the molar
ratio """
enthalpies = []
mol_coefficients = []
for pair in itertools.combinations(self.element_list, 2):
enthalpies.append(mm_data.MixingEnthalpy().get_mixing_enthalpy(*pair))
for molies in itertools.combinations(self.mol_ratio, 2):
mol_coefficients.append(4 * np.product(molies))
enthalpy = np.dot(enthalpies, mol_coefficients)
return enthalpy
'''
5. standard deviation of enthalpy
'''
def std_enthalpy_mixing(self):
"""function to return the standard deviation of enthalpy of mixing 混合焓的标准偏差 (sigma_h) of the alloy"""
sigma_h = 0
H = np.zeros((len(self.element_list), len(self.element_list)))
for i in range(len(self.element_list)):
for j in range(len(self.element_list)):
if i != j:
H[i][j] = mm_data.MixingEnthalpy().get_mixing_enthalpy(self.element_list[i], self.element_list[j])
for i in range(len(self.element_list)):
for j in range(len(self.element_list)):
if i != j:
sigma_h += self.mol_ratio[i] * self.mol_ratio[j] * np.square(H[i][j] - self.enthalpy_mixing())
sigma_h = sigma_h / 2
return np.sqrt(sigma_h)
'''
12. Omega omega
'''
def calc_omega(self):
"""function to return the omega value of the alloy"""
if np.abs(self.mix_enthalpy) < 1e-6:
self.mix_enthalpy = 1e-6
return self.Tm * self.mix_entropy / (np.abs(self.mix_enthalpy) * 1000)
'''
8. average electronegativity
'''
def mean_electronegativity(self):
"""function to return the mean electronegativity 电负性的均值 (x) of the alloy"""
x_list = []
for i in range(len(self.element_list)):
x_list.append(self.element_list[i].X)
x_avg = np.dot(x_list, self.mol_ratio)
return x_avg
'''
9. standard deviation of electronegativity
'''
def std_electronegativity(self):
"""function to return the standard deviation (in percentage) of electronegativity 电负性的标准偏差 (sigma_x) of the alloy"""
sigma_x = 0
x_list = []
for i in range(len(self.element_list)):
x_list.append(self.element_list[i].X)
for j in range(len(self.element_list)):
sigma_x += self.mol_ratio[j] * np.square(x_list[j] - self.x)
return np.sqrt(sigma_x) / self.x
'''
10. valence electron concentration
'''
def num_ve(self, element):
"""function to return the number of valence electron of the element元素的价电子"""
e_structure = element.full_electronic_structure
outer = element.full_electronic_structure[-1][0]
num_e = 0
for t in e_structure:
if t[0] == outer - 1 and t[1] == 'd':
num_e += t[2]
if t[0] == outer:
num_e += t[2]
return num_e
'''
average of valence electron concentration
'''
def average_vec(self):
"""function to return the average of valence electron concentration 价电子浓度的均值 (vec) of the alloy"""
vec = 0
for i in range(len(self.element_list)):
vec += self.mol_ratio[i] * self.num_ve(self.element_list[i])
return vec
'''
11. standard deviation of valence electron concentration
'''
def std_vec(self):
"""function to return the standard deviation of valence electron concentration 价电子浓度的标准偏差 (sigma_vec) of the alloy"""
sigma_vec = 0
vec_list = []
for i in range(len(self.element_list)):
vec_list.append(self.num_ve(self.element_list[i]))
for j in range(len(self.element_list)):
sigma_vec += self.mol_ratio[j] * np.square(vec_list[j] - self.vec)
return np.sqrt(sigma_vec)
'''
average of bulk modulus
'''
def mean_bulk_modulus(self):
"""function to return the average of bulk modulus (k)体积弹性模量 of the alloy"""
k = 0
for i in range(len(self.element_list)):
if self.element_list[i].bulk_modulus is None:
print(self.element_list[i])
else:
k += self.mol_ratio[i] * self.element_list[i].bulk_modulus
return k
'''
standard deviation of bulk modulus
'''
def std_bulk_modulus(self):
"""function to return the standard deviation of bulk modulus (k)体积弹性模量 of the alloy"""
sigma_k = 0
k_list = []
for i in range(len(self.element_list)):
k_list.append(self.element_list[i].bulk_modulus)
for j in range(len(self.element_list)):
if self.element_list[i].bulk_modulus is None:
print(self.element_list[i])
else:
sigma_k += self.mol_ratio[j] * np.square(k_list[j] - self.k)
return np.sqrt(sigma_k)
'''
13. density
'''
def calc_density(self):
"""function to return the density (g/cm^3) of the alloy"""
mass = 0
volume = 0
for i in range(len(self.element_list)):
mass += float(self.element_list[i].atomic_mass) * self.mol_ratio[i]
volume += self.mol_ratio[i] * self.element_list[i].molar_volume
return mass / volume
'''
14. price/element cost
'''
def calc_price(self):
"""function to return the price (USD/kg) of the alloy"""
total_mass = 0
total_price = 0
for i in range(len(self.element_list)):
if not str(self.element_list[i]) in price_dic:
return 'unknown'
mass = float(self.element_list[i].atomic_mass) * self.mol_ratio[i]
total_mass += mass
total_price += mass * price_dic[str(self.element_list[i])]
return format(total_price / total_mass, '.2f')
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