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JARVIS-ML-CFID-descriptors and material properties
Version 2 2020-04-29, 22:50Version 2 2020-04-29, 22:50
Version 1 2018-07-26, 22:08Version 1 2018-07-26, 22:08
dataset
posted on 2020-04-29, 22:50 authored by Kamal ChoudharyKamal ChoudharyClassical force-field inspired descriptors (CFID) for more than 35000 materials and their material properties such as bandgap, formation energies, modulus of elasticity etc.
See JARVIS-ML:
https://jarvis.nist.gov/
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Example:
import os,json
import pandas as pd
f = open(os.path.join(os.getcwd(),'jml_3d-4-26-2020.json'),'r')
dataml=json.load(f)
f.close()
df=pd.DataFrame(dataml)
typical_data_ranges = {'formation_energy_peratom': [-5, 5], 'optb88vdw_bandgap': [0, 10], 'mbj_bandgap': [0, 10], 'bulk_modulus_kv': [0, 250], 'shear_modulus_gv': [0, 250], 'epsx': [0, 60], 'epsy': [0, 60], 'epsz': [0, 60], 'mepsx': [0, 60], 'mepsy': [0, 60], 'mepsz': [0, 60], 'n-Seebeck': [-600, 10], 'n-powerfact': [0, 5000], 'p-Seebeck': [-10, 600], 'p-powerfact': [0, 5000], 'slme': [0, 40], 'spillage': [0, 4], 'encut': [0, 2000], 'kpoint_length_unit': [0, 200], 'dfpt_piezo_max_dielectric': [0, 100], 'dfpt_piezo_max_dij': [0, 3000], 'dfpt_piezo_max_eij': [0, 10], 'ehull': [0, 1], 'electron_avg_effective_masses_300K': [0, 3], 'hole_avg_effective_masses_300K': [0, 3], 'exfoliation_energy': [0, 1000], 'magmom_oszicar': [0, 10], 'max_ir_mode': [0, 4000], 'total_energy_per_atom': [-10, 3]}
import numpy as np
%matplotlib inline
import matplotlib.pyplot as plt
val=np.array(df['formation_energy_peratom'].replace('na',np.nan).dropna().values,dtype='float')
plt.hist(val,bins=np.arange(-4,4,.5))
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For more details about using the dataset, use the jupyter-notebooks:
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