def test_from_structure_NPT(self):
from pymatgen import Lattice, Structure
coords1 = np.array([[0.0, 0.0, 0.0], [0.5, 0.5, 0.5]])
coords2 = np.array([[0.0, 0.0, 0.0], [0.6, 0.6, 0.6]])
coords3 = np.array([[0.0, 0.0, 0.0], [0.7, 0.7, 0.7]])
lattice1 = Lattice.from_parameters(
a=2.0, b=2.0, c=2.0, alpha=90, beta=90, gamma=90
)
lattice2 = Lattice.from_parameters(
a=2.1, b=2.1, c=2.1, alpha=90, beta=90, gamma=90
)
lattice3 = Lattice.from_parameters(
a=2.0, b=2.0, c=2.0, alpha=90, beta=90, gamma=90
)
s1 = Structure(coords=coords1, lattice=lattice1, species=["F", "Li"])
s2 = Structure(coords=coords2, lattice=lattice2, species=["F", "Li"])
s3 = Structure(coords=coords3, lattice=lattice3, species=["F", "Li"])
structures = [s1, s2, s3]
d = DiffusionAnalyzer.from_structures(
structures,
specie="Li",
temperature=500.0,
time_step=2.0,
step_skip=1,
smoothed=None,
)
self.assertArrayAlmostEqual(
d.disp[1],
np.array([[0.0, 0.0, 0.0], [0.21, 0.21, 0.21], [0.40, 0.40, 0.40]]),
)
def test_from_structure_NPT( self ):
from pymatgen import Structure, Lattice
coords1 = np.array([[0.0, 0.0, 0.0], [0.5, 0.5, 0.5]] )
coords2 = np.array([[0.0, 0.0, 0.0], [0.6, 0.6, 0.6]] )
coords3 = np.array([[0.0, 0.0, 0.0], [0.7, 0.7, 0.7]] )
lattice1 = Lattice.from_parameters(a=2.0, b=2.0, c=2.0, alpha=90, beta=90, gamma=90)
lattice2 = Lattice.from_parameters(a=2.1, b=2.1, c=2.1, alpha=90, beta=90, gamma=90)
lattice3 = Lattice.from_parameters(a=2.0, b=2.0, c=2.0, alpha=90, beta=90, gamma=90)
s1 = Structure(coords=coords1, lattice=lattice1, species=['F', 'Li'])
s2 = Structure(coords=coords2, lattice=lattice2, species=['F', 'Li'])
s3 = Structure(coords=coords3, lattice=lattice3, species=['F', 'Li'])
structures = [s1, s2, s3]
d = DiffusionAnalyzer.from_structures( structures, specie='Li', temperature=500.0, time_step=2.0, step_skip=1, smoothed=None )
self.assertArrayAlmostEqual(d.disp[1], np.array([[0., 0., 0. ],
[0.21, 0.21, 0.21],
[0.40, 0.40, 0.40]]))
def test_init(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(os.path.join(test_dir, "DiffusionAnalyzer.json")) as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
# large tolerance because scipy constants changed between 0.16.1 and 0.17
self.assertAlmostEqual(d.conductivity, 74.165372613735684, 4)
self.assertAlmostEqual(d.chg_conductivity, 232.827958801, 4)
self.assertAlmostEqual(d.diffusivity, 1.16083658794e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 3.64565578208e-06, 7)
self.assertAlmostEqual(d.conductivity_std_dev, 0.0097244677795984488, 7)
self.assertAlmostEqual(d.diffusivity_std_dev, 9.1013023085561779e-09, 7)
self.assertAlmostEqual(d.chg_diffusivity_std_dev, 7.20911399729e-10, 5)
self.assertAlmostEqual(d.haven_ratio, 0.31854161048867402, 7)
self.assertArrayAlmostEqual(
d.conductivity_components,
[45.7903694, 26.1651956, 150.5406140], 3)
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.49601236e-07, 4.90254273e-07, 2.24649255e-06])
self.assertArrayAlmostEqual(
d.conductivity_components_std_dev,
[0.0063566, 0.0180854, 0.0217918]
)
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[8.9465670e-09, 2.4931224e-08, 2.2636384e-08]
)
self.assertArrayAlmostEqual(
d.mscd[0:4],
[0.69131064, 0.71794072, 0.74315283, 0.76703961]
)
self.assertArrayAlmostEqual(
d.max_ion_displacements,
[1.4620659693989553, 1.2787303484445025, 3.419618540097756,
2.340104469126246, 2.6080973517594233, 1.3928579365672844,
1.3561505956708932, 1.6699242923686253, 1.0352389639563648,
1.1662520093955808, 1.2322019205885841, 0.8094210554832534,
1.9917808504954169, 1.2684148391206396, 2.392633794162402,
2.566313049232671, 1.3175030435622759, 1.4628945430952793,
1.0984921286753002, 1.2864482076554093, 0.655567027815413,
0.5986961164605746, 0.5639091444309045, 0.6166004192954059,
0.5997911580422605, 0.4374606277579815, 1.1865683960470783,
0.9017064371676591, 0.6644840367853767, 1.0346375380664645,
0.6177630142863979, 0.7952002051914302, 0.7342686123054011,
0.7858047956905577, 0.5570732369065661, 1.0942937746885417,
0.6509372395308788, 1.0876687380413455, 0.7058162184725,
0.8298306317598585, 0.7813913747621343, 0.7337655232056153,
0.9057161616236746, 0.5979093093186919, 0.6830333586985015,
0.7926500894084628, 0.6765180009988608, 0.8555866032968998,
0.713087091642237, 0.7621007695790749])
self.assertEqual(d.sq_disp_ions.shape, (50, 206))
self.assertEqual(d.lattices.shape, (1, 3, 3))
self.assertEqual(d.mscd.shape, (206,))
self.assertEqual(d.mscd.shape, d.msd.shape)
self.assertAlmostEqual(d.max_framework_displacement, 1.18656839605)
ss = list(d.get_drift_corrected_structures(10, 1000, 20))
self.assertEqual(len(ss), 50)
n = random.randint(0, 49)
n_orig = n * 20 + 10
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords + d.drift[:, n_orig, :],
d.disp[:, n_orig, :])
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
#Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="max")
self.assertAlmostEqual(d.conductivity, 74.165372613735684, 4)
self.assertAlmostEqual(d.diffusivity, 1.14606446822e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.318541610489, 6)
self.assertAlmostEqual(d.chg_conductivity, 232.827958801, 4)
self.assertAlmostEqual(d.chg_diffusivity, 3.64565578208e-06, 7)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed=False)
self.assertAlmostEqual(d.conductivity, 27.20479170406027, 4)
self.assertAlmostEqual(d.diffusivity, 4.25976905436e-07, 7)
self.assertAlmostEqual(d.chg_diffusivity, 1.6666666666666667e-17, 3)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip,
smoothed="constant", avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404056230438741, 4)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
self.assertAlmostEqual(d.chg_conductivity, 1.06440821953e-09, 4)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(ValueError, DiffusionAnalyzer,
d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="constant",
avg_nsteps=2000)
d = DiffusionAnalyzer.from_structures(
list(d.get_drift_corrected_structures()),
d.specie, d.temperature, d.time_step,
d.step_skip, smoothed=d.smoothed, avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404056230438741, 4)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
d.export_msdt("test.csv")
with open("test.csv") as f:
data = []
for row in csv.reader(f):
if row:
data.append(row)
data.pop(0)
data = np.array(data, dtype=np.float64)
self.assertArrayAlmostEqual(data[:, 1], d.msd)
self.assertArrayAlmostEqual(data[:, -1], d.mscd)
os.remove("test.csv")
def test_init_npt(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(os.path.join(test_dir, "DiffusionAnalyzer_NPT.json"), 'r') as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
# large tolerance because scipy constants changed between 0.16.1 and 0.17
self.assertAlmostEqual(d.conductivity, 499.15058192970508, 4)
self.assertAlmostEqual(d.chg_conductivity, 1219.59633107, 4)
self.assertAlmostEqual(d.diffusivity, 8.40265434771e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 2.05305709033e-05, 6)
self.assertAlmostEqual(d.conductivity_std_dev, 0.10368477696021029, 7)
self.assertAlmostEqual(d.diffusivity_std_dev, 9.1013023085561779e-09, 7)
self.assertAlmostEqual(d.chg_diffusivity_std_dev, 1.20834853646e-08, 6)
self.assertAlmostEqual(d.haven_ratio, 0.409275240679, 7)
self.assertArrayAlmostEqual(
d.conductivity_components,
[455.178101, 602.252644, 440.0210014], 3)
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.66242570e-06, 1.01382648e-05, 7.40727250e-06])
self.assertArrayAlmostEqual(
d.conductivity_components_std_dev,
[0.1196577, 0.0973347, 0.1525400]
)
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[2.0143072e-09, 1.6385239e-09, 2.5678445e-09]
)
self.assertArrayAlmostEqual(
d.max_ion_displacements,
[1.13147881, 0.79899554, 1.04153733, 0.96061850,
0.83039864, 0.70246715, 0.61365911, 0.67965179,
1.91973907, 1.69127386, 1.60568746, 1.35587641,
1.03280378, 0.99202692, 2.03359655, 1.03760269,
1.40228350, 1.36315080, 1.27414979, 1.26742035,
0.88199589, 0.97700804, 1.11323184, 1.00139511,
2.94164403, 0.89438909, 1.41508334, 1.23660358,
0.39322939, 0.54264064, 1.25291806, 0.62869809,
0.40846708, 1.43415505, 0.88891241, 0.56259128,
0.81712740, 0.52700441, 0.51011733, 0.55557882,
0.49131002, 0.66740277, 0.57798671, 0.63521025,
0.50277142, 0.52878021, 0.67803443, 0.81161269,
0.46486345, 0.47132761, 0.74301293, 0.79285519,
0.48789600, 0.61776836, 0.60695847, 0.67767756,
0.70972268, 1.08232442, 0.87871177, 0.84674206,
0.45694693, 0.60417985, 0.61652272, 0.66444583,
0.52211986, 0.56544134, 0.43311443, 0.43027547,
1.10730439, 0.59829728, 0.52270635, 0.72327608,
1.02919775, 0.84423208, 0.61694764, 0.72795752,
0.72957755, 0.55491631, 0.68507454, 0.76745343,
0.96346584, 0.66672645, 1.06810107, 0.65705843])
self.assertEqual(d.sq_disp_ions.shape, (84, 217))
self.assertEqual(d.lattices.shape, (1001, 3, 3))
self.assertEqual(d.mscd.shape, (217,))
self.assertEqual(d.mscd.shape, d.msd.shape)
self.assertAlmostEqual(d.max_framework_displacement, 1.43415505156)
ss = list(d.get_drift_corrected_structures(10, 1000, 20))
self.assertEqual(len(ss), 50)
n = random.randint(0, 49)
n_orig = n * 20 + 10
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords + d.drift[:, n_orig, :],
d.disp[:, n_orig, :])
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
# Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="max")
self.assertAlmostEqual(d.conductivity, 499.15058192970508, 4)
self.assertAlmostEqual(d.diffusivity, 8.40265434771e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.409275240679, 7)
self.assertAlmostEqual(d.chg_diffusivity, 2.05305709033e-05, 7)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed=False)
self.assertAlmostEqual(d.conductivity, 406.5965396, 4)
self.assertAlmostEqual(d.diffusivity, 6.8446082e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 1.03585877962e-05, 6)
self.assertAlmostEqual(d.haven_ratio, 0.6607665413, 6)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip,
smoothed="constant", avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 425.7789898, 4)
self.assertAlmostEqual(d.diffusivity, 7.167523809142514e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 9.33480892187e-06, 6)
self.assertAlmostEqual(d.haven_ratio, 0.767827586952, 6)
self.assertAlmostEqual(d.chg_conductivity, 554.524214937, 6)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(ValueError, DiffusionAnalyzer,
d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="constant",
avg_nsteps=2000)
d = DiffusionAnalyzer.from_structures(
list(d.get_drift_corrected_structures()),
d.specie, d.temperature, d.time_step,
d.step_skip, smoothed=d.smoothed, avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 425.77898986201302, 4)
self.assertAlmostEqual(d.diffusivity, 7.1675238091425148e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.767827586952, 7)
self.assertAlmostEqual(d.chg_conductivity, 554.524214937, 6)
d.export_msdt("test.csv")
with open("test.csv") as f:
data = []
for row in csv.reader(f):
if row:
data.append(row)
data.pop(0)
data = np.array(data, dtype=np.float64)
self.assertArrayAlmostEqual(data[:, 1], d.msd)
self.assertArrayAlmostEqual(data[:, -1], d.mscd)
os.remove("test.csv")
分析AIMD结果,计算MSD 和 conductivity
'''
import os
from pymatgen.core.trajectory import Trajectory
from pymatgen.io.vasp.outputs import Xdatcar
from pymatgen import Structure
from pymatgen.analysis.diffusion_analyzer import DiffusionAnalyzer
import numpy as np
import pickle
# 这一步是读取 XDATCAR,得到一系列结构信息
traj = Trajectory.from_file('XDATCAR')
# 这一步是实例化 DiffusionAnalyzer 的类
# 并用 from_structures 方法初始化这个类; 900 是温度,2 是POTIM 的值,1是间隔步数
# 间隔步数(step_skip)不太容易理解,但是根据官方教程:
# dt = timesteps * self.time_step * self.step_skip
diff = DiffusionAnalyzer.from_structures(traj,'Li',900,2,1)
# 可以用内置的 plot_msd 方法画出 MSD 图像
# 有些终端不能显示图像,这时候可以调用 export_msdt() 方法,得到数据后再自己作图
diff.plot_msd()
# 接下来直接得到 离子迁移率, 单位是 mS/cm
C = diff.conductivity
with open('result.dat','w') as f:
f.write('# AIMD result for Li-ion\n')
f.write('temp\tconductivity\n')
f.write('%d\t%.2f\n' %(900,C))
def test_init(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(
os.path.join(PymatgenTest.TEST_FILES_DIR,
"DiffusionAnalyzer.json")) as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
# large tolerance because scipy constants changed between 0.16.1 and 0.17
self.assertAlmostEqual(d.conductivity, 74.165372613735684, 4)
self.assertAlmostEqual(d.chg_conductivity, 232.8278799754324, 4)
self.assertAlmostEqual(d.diffusivity, 1.16083658794e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 3.64565578208e-06, 7)
self.assertAlmostEqual(d.conductivity_std_dev,
0.0097244677795984488, 7)
self.assertAlmostEqual(d.diffusivity_std_dev,
9.1013023085561779e-09, 7)
self.assertAlmostEqual(d.chg_diffusivity_std_dev,
7.20911399729e-10, 5)
self.assertAlmostEqual(d.haven_ratio, 0.31854161048867402, 7)
self.assertArrayAlmostEqual(d.conductivity_components,
[45.7903694, 26.1651956, 150.5406140],
3)
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.49601236e-07, 4.90254273e-07, 2.24649255e-06],
)
self.assertArrayAlmostEqual(d.conductivity_components_std_dev,
[0.0063566, 0.0180854, 0.0217918])
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[8.9465670e-09, 2.4931224e-08, 2.2636384e-08],
)
self.assertArrayAlmostEqual(
d.mscd[0:4], [0.69131064, 0.71794072, 0.74315283, 0.76703961])
self.assertArrayAlmostEqual(
d.max_ion_displacements,
[
1.4620659693989553,
1.2787303484445025,
3.419618540097756,
2.340104469126246,
2.6080973517594233,
1.3928579365672844,
1.3561505956708932,
1.6699242923686253,
1.0352389639563648,
1.1662520093955808,
1.2322019205885841,
0.8094210554832534,
1.9917808504954169,
1.2684148391206396,
2.392633794162402,
2.566313049232671,
1.3175030435622759,
1.4628945430952793,
1.0984921286753002,
1.2864482076554093,
0.655567027815413,
0.5986961164605746,
0.5639091444309045,
0.6166004192954059,
0.5997911580422605,
0.4374606277579815,
1.1865683960470783,
0.9017064371676591,
0.6644840367853767,
1.0346375380664645,
0.6177630142863979,
0.7952002051914302,
0.7342686123054011,
0.7858047956905577,
0.5570732369065661,
1.0942937746885417,
0.6509372395308788,
1.0876687380413455,
0.7058162184725,
0.8298306317598585,
0.7813913747621343,
0.7337655232056153,
0.9057161616236746,
0.5979093093186919,
0.6830333586985015,
0.7926500894084628,
0.6765180009988608,
0.8555866032968998,
0.713087091642237,
0.7621007695790749,
],
)
self.assertEqual(d.sq_disp_ions.shape, (50, 206))
self.assertEqual(d.lattices.shape, (1, 3, 3))
self.assertEqual(d.mscd.shape, (206, ))
self.assertEqual(d.mscd.shape, d.msd.shape)
self.assertAlmostEqual(d.max_framework_displacement, 1.18656839605)
ss = list(d.get_drift_corrected_structures(10, 1000, 20))
self.assertEqual(len(ss), 50)
n = random.randint(0, 49)
n_orig = n * 20 + 10
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords +
d.drift[:, n_orig, :],
d.disp[:, n_orig, :],
)
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
# Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="max",
)
self.assertAlmostEqual(d.conductivity, 74.165372613735684, 4)
self.assertAlmostEqual(d.diffusivity, 1.14606446822e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.318541610489, 6)
self.assertAlmostEqual(d.chg_conductivity, 232.8278799754324, 4)
self.assertAlmostEqual(d.chg_diffusivity, 3.64565578208e-06, 7)
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed=False,
)
self.assertAlmostEqual(d.conductivity, 27.20479170406027, 4)
self.assertAlmostEqual(d.diffusivity, 4.25976905436e-07, 7)
self.assertAlmostEqual(d.chg_diffusivity, 1.6666666666666667e-17,
3)
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=100,
)
self.assertAlmostEqual(d.conductivity, 47.404056230438741, 4)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
self.assertAlmostEqual(d.chg_conductivity, 1.06440821953e-09, 4)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(
ValueError,
DiffusionAnalyzer,
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=2000,
)
d = DiffusionAnalyzer.from_structures(
list(d.get_drift_corrected_structures()),
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed=d.smoothed,
avg_nsteps=100,
)
self.assertAlmostEqual(d.conductivity, 47.404056230438741, 4)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
d.export_msdt("test.csv")
with open("test.csv") as f:
data = []
for row in csv.reader(f):
if row:
data.append(row)
data.pop(0)
data = np.array(data, dtype=np.float64)
self.assertArrayAlmostEqual(data[:, 1], d.msd)
self.assertArrayAlmostEqual(data[:, -1], d.mscd)
os.remove("test.csv")
def test_init_npt(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(
os.path.join(PymatgenTest.TEST_FILES_DIR,
"DiffusionAnalyzer_NPT.json"), "r") as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
# large tolerance because scipy constants changed between 0.16.1 and 0.17
self.assertAlmostEqual(d.conductivity, 499.1504129387108, 4)
self.assertAlmostEqual(d.chg_conductivity, 1219.5959181678043, 4)
self.assertAlmostEqual(d.diffusivity, 8.40265434771e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 2.05305709033e-05, 6)
self.assertAlmostEqual(d.conductivity_std_dev, 0.10368477696021029,
7)
self.assertAlmostEqual(d.diffusivity_std_dev,
9.1013023085561779e-09, 7)
self.assertAlmostEqual(d.chg_diffusivity_std_dev,
1.20834853646e-08, 6)
self.assertAlmostEqual(d.haven_ratio, 0.409275240679, 7)
self.assertArrayAlmostEqual(d.conductivity_components,
[455.178101, 602.252644, 440.0210014],
3)
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.66242570e-06, 1.01382648e-05, 7.40727250e-06],
)
self.assertArrayAlmostEqual(d.conductivity_components_std_dev,
[0.1196577, 0.0973347, 0.1525400])
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[2.0143072e-09, 1.6385239e-09, 2.5678445e-09],
)
self.assertArrayAlmostEqual(
d.max_ion_displacements,
[
1.13147881,
0.79899554,
1.04153733,
0.96061850,
0.83039864,
0.70246715,
0.61365911,
0.67965179,
1.91973907,
1.69127386,
1.60568746,
1.35587641,
1.03280378,
0.99202692,
2.03359655,
1.03760269,
1.40228350,
1.36315080,
1.27414979,
1.26742035,
0.88199589,
0.97700804,
1.11323184,
1.00139511,
2.94164403,
0.89438909,
1.41508334,
1.23660358,
0.39322939,
0.54264064,
1.25291806,
0.62869809,
0.40846708,
1.43415505,
0.88891241,
0.56259128,
0.81712740,
0.52700441,
0.51011733,
0.55557882,
0.49131002,
0.66740277,
0.57798671,
0.63521025,
0.50277142,
0.52878021,
0.67803443,
0.81161269,
0.46486345,
0.47132761,
0.74301293,
0.79285519,
0.48789600,
0.61776836,
0.60695847,
0.67767756,
0.70972268,
1.08232442,
0.87871177,
0.84674206,
0.45694693,
0.60417985,
0.61652272,
0.66444583,
0.52211986,
0.56544134,
0.43311443,
0.43027547,
1.10730439,
0.59829728,
0.52270635,
0.72327608,
1.02919775,
0.84423208,
0.61694764,
0.72795752,
0.72957755,
0.55491631,
0.68507454,
0.76745343,
0.96346584,
0.66672645,
1.06810107,
0.65705843,
],
)
self.assertEqual(d.sq_disp_ions.shape, (84, 217))
self.assertEqual(d.lattices.shape, (1001, 3, 3))
self.assertEqual(d.mscd.shape, (217, ))
self.assertEqual(d.mscd.shape, d.msd.shape)
self.assertAlmostEqual(d.max_framework_displacement, 1.43415505156)
ss = list(d.get_drift_corrected_structures(10, 1000, 20))
self.assertEqual(len(ss), 50)
n = random.randint(0, 49)
n_orig = n * 20 + 10
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords +
d.drift[:, n_orig, :],
d.disp[:, n_orig, :],
)
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
# Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="max",
)
self.assertAlmostEqual(d.conductivity, 499.1504129387108, 4)
self.assertAlmostEqual(d.diffusivity, 8.40265434771e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.409275240679, 7)
self.assertAlmostEqual(d.chg_diffusivity, 2.05305709033e-05, 7)
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed=False,
)
self.assertAlmostEqual(d.conductivity, 406.5964019770787, 4)
self.assertAlmostEqual(d.diffusivity, 6.8446082e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 1.03585877962e-05, 6)
self.assertAlmostEqual(d.haven_ratio, 0.6607665413, 6)
d = DiffusionAnalyzer(
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=100,
)
self.assertAlmostEqual(d.conductivity, 425.77884571149525, 4)
self.assertAlmostEqual(d.diffusivity, 7.167523809142514e-06, 7)
self.assertAlmostEqual(d.chg_diffusivity, 9.33480892187e-06, 6)
self.assertAlmostEqual(d.haven_ratio, 0.767827586952, 6)
self.assertAlmostEqual(d.chg_conductivity, 554.5240271992852, 6)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(
ValueError,
DiffusionAnalyzer,
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=2000,
)
d = DiffusionAnalyzer.from_structures(
list(d.get_drift_corrected_structures()),
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed=d.smoothed,
avg_nsteps=100,
)
self.assertAlmostEqual(d.conductivity, 425.7788457114952, 4)
self.assertAlmostEqual(d.diffusivity, 7.1675238091425148e-06, 7)
self.assertAlmostEqual(d.haven_ratio, 0.767827586952, 7)
self.assertAlmostEqual(d.chg_conductivity, 554.5240271992852, 6)
d.export_msdt("test.csv")
with open("test.csv") as f:
data = []
for row in csv.reader(f):
if row:
data.append(row)
data.pop(0)
data = np.array(data, dtype=np.float64)
self.assertArrayAlmostEqual(data[:, 1], d.msd)
self.assertArrayAlmostEqual(data[:, -1], d.mscd)
os.remove("test.csv")
def test_init(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(os.path.join(test_dir, "DiffusionAnalyzer.json")) as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
self.assertAlmostEqual(d.conductivity, 74.165372208150615, 7)
self.assertAlmostEqual(d.diffusivity, 1.16083658794e-06, 7)
self.assertAlmostEqual(d.conductivity_std_dev,
0.0097244677795984488, 7)
self.assertAlmostEqual(d.diffusivity_std_dev,
9.1013023085561779e-09, 7)
self.assertArrayAlmostEqual(d.conductivity_components,
[45.9109701, 26.28563, 150.5405718])
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.49601236e-07, 4.90254273e-07, 2.24649255e-06])
self.assertArrayAlmostEqual(d.conductivity_components_std_dev,
[0.0063579, 0.0180862, 0.0217917])
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[8.9465670e-09, 2.4931224e-08, 2.2636384e-08])
self.assertArrayAlmostEqual(d.max_ion_displacements, [
1.4620659693989553, 1.2787303484445025, 3.419618540097756,
2.340104469126246, 2.6080973517594233, 1.3928579365672844,
1.3561505956708932, 1.6699242923686253, 1.0352389639563648,
1.1662520093955808, 1.2322019205885841, 0.8094210554832534,
1.9917808504954169, 1.2684148391206396, 2.392633794162402,
2.566313049232671, 1.3175030435622759, 1.4628945430952793,
1.0984921286753002, 1.2864482076554093, 0.655567027815413,
0.5986961164605746, 0.5639091444309045, 0.6166004192954059,
0.5997911580422605, 0.4374606277579815, 1.1865683960470783,
0.9017064371676591, 0.6644840367853767, 1.0346375380664645,
0.6177630142863979, 0.7952002051914302, 0.7342686123054011,
0.7858047956905577, 0.5570732369065661, 1.0942937746885417,
0.6509372395308788, 1.0876687380413455, 0.7058162184725,
0.8298306317598585, 0.7813913747621343, 0.7337655232056153,
0.9057161616236746, 0.5979093093186919, 0.6830333586985015,
0.7926500894084628, 0.6765180009988608, 0.8555866032968998,
0.713087091642237, 0.7621007695790749
])
self.assertEqual(d.sq_disp_ions.shape, (50, 206))
self.assertAlmostEqual(d.max_framework_displacement, 1.18656839605)
ss = list(d.get_drift_corrected_structures())
self.assertEqual(len(ss), 1000)
n = random.randint(0, 999)
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords + d.drift[:, n, :],
d.disp[:, n, :])
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
#Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="max")
self.assertAlmostEqual(d.conductivity, 74.16537220815061, 7)
self.assertAlmostEqual(d.diffusivity, 1.14606446822e-06, 7)
d = DiffusionAnalyzer(d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed=False)
self.assertAlmostEqual(d.conductivity, 27.2047915553, 7)
self.assertAlmostEqual(d.diffusivity, 4.25976905436e-07, 7)
d = DiffusionAnalyzer(d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404055971202155, 7)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(ValueError,
DiffusionAnalyzer,
d.structure,
d.disp,
d.specie,
d.temperature,
d.time_step,
d.step_skip,
smoothed="constant",
avg_nsteps=2000)
d = DiffusionAnalyzer.from_structures(list(
d.get_drift_corrected_structures()),
d.specie,
d.temperature,
d.time_step,
d.step_skip,
d.smoothed,
avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404055971202155, 7)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
#%%
from pymatgen import Molecule, Structure, Lattice
from pymatgen.analysis.diffusion_analyzer import DiffusionAnalyzer
import os
os.chdir('/home/jinho93/oxides/perobskite/lanthanum-aluminate/slab/gulp/stoichiometric/more')
# os.chdir('/home/jinho93/new/oxides/perobskite/lanthanum-aluminate/slab/gulp/nostochio/La-vac')
with open('lao.xyz') as f:
lines = f.readlines()
ss = []
atoms_number = 802
for i in range(len(lines) // atoms_number // 5):
mole = Molecule.from_str(''.join(lines[atoms_number * i:atoms_number * (i + 1)]), fmt='xyz')
l = Lattice([[15.2882,0,0], [0,15.2882, 0], [0,0,50]])
s = Structure(l, mole.species, mole.cart_coords, coords_are_cartesian=True)
ss.append(s)
from pymatgen.core import Element, Specie
d = DiffusionAnalyzer.from_structures(ss, 'La', 300, len(ss) // 2, step_skip=2)
d.get_msd_plot()
#%%
import numpy as np
np.savetxt('msd.dat', d.dt)
#%%
from pymatgen.core.lattice import Lattice
from pymatgen.io.xyz import XYZ
from pymatgen import Structure
from pymatgen.analysis.diffusion_analyzer import DiffusionAnalyzer
import os
import numpy as np
os.chdir('/home/jinho93/oxides/wurtzite/zno/cp2k/1.aimd/3.16A/30/3.fix')
x = XYZ.from_file('526.xyz')
lat = Lattice(np.diag([16.02, 16.67, 40.67]))
s = [
Structure(lat, r.species, r.cart_coords, coords_are_cartesian=True)
for r in x.all_molecules
]
#%%
from pymatgen.analysis.diffusion_analyzer import DiffusionAnalyzer
d = DiffusionAnalyzer.from_structures(s, 'Zn', 600, 500, 2)
d.get_msd_plot()
def test_init(self):
# Diffusion vasprun.xmls are rather large. We are only going to use a
# very small preprocessed run for testing. Note that the results are
# unreliable for short runs.
with open(os.path.join(test_dir, "DiffusionAnalyzer.json")) as f:
dd = json.load(f)
d = DiffusionAnalyzer.from_dict(dd)
self.assertAlmostEqual(d.conductivity, 74.165372208150615, 7)
self.assertAlmostEqual(d.diffusivity, 1.16083658794e-06, 7)
self.assertAlmostEqual(d.conductivity_std_dev, 0.0097244677795984488, 7)
self.assertAlmostEqual(d.diffusivity_std_dev, 9.1013023085561779e-09, 7)
self.assertArrayAlmostEqual(
d.conductivity_components,
[45.9109701, 26.28563 , 150.5405718])
self.assertArrayAlmostEqual(
d.diffusivity_components,
[7.49601236e-07, 4.90254273e-07, 2.24649255e-06])
self.assertArrayAlmostEqual(
d.conductivity_components_std_dev,
[0.0063579, 0.0180862, 0.0217917]
)
self.assertArrayAlmostEqual(
d.diffusivity_components_std_dev,
[8.9465670e-09, 2.4931224e-08, 2.2636384e-08]
)
self.assertArrayAlmostEqual(
d.max_ion_displacements,
[1.4620659693989553, 1.2787303484445025, 3.419618540097756,
2.340104469126246, 2.6080973517594233, 1.3928579365672844,
1.3561505956708932, 1.6699242923686253, 1.0352389639563648,
1.1662520093955808, 1.2322019205885841, 0.8094210554832534,
1.9917808504954169, 1.2684148391206396, 2.392633794162402,
2.566313049232671, 1.3175030435622759, 1.4628945430952793,
1.0984921286753002, 1.2864482076554093, 0.655567027815413,
0.5986961164605746, 0.5639091444309045, 0.6166004192954059,
0.5997911580422605, 0.4374606277579815, 1.1865683960470783,
0.9017064371676591, 0.6644840367853767, 1.0346375380664645,
0.6177630142863979, 0.7952002051914302, 0.7342686123054011,
0.7858047956905577, 0.5570732369065661, 1.0942937746885417,
0.6509372395308788, 1.0876687380413455, 0.7058162184725,
0.8298306317598585, 0.7813913747621343, 0.7337655232056153,
0.9057161616236746, 0.5979093093186919, 0.6830333586985015,
0.7926500894084628, 0.6765180009988608, 0.8555866032968998,
0.713087091642237, 0.7621007695790749])
self.assertEqual(d.sq_disp_ions.shape, (50, 206))
self.assertAlmostEqual(d.max_framework_displacement, 1.18656839605)
ss = list(d.get_drift_corrected_structures())
self.assertEqual(len(ss), 1000)
n = random.randint(0, 999)
self.assertArrayAlmostEqual(
ss[n].cart_coords - d.structure.cart_coords + d.drift[:, n, :],
d.disp[:, n, :])
d = DiffusionAnalyzer.from_dict(d.as_dict())
self.assertIsInstance(d, DiffusionAnalyzer)
#Ensure summary dict is json serializable.
json.dumps(d.get_summary_dict(include_msd_t=True))
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="max")
self.assertAlmostEqual(d.conductivity, 74.16537220815061, 7)
self.assertAlmostEqual(d.diffusivity, 1.14606446822e-06, 7)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed=False)
self.assertAlmostEqual(d.conductivity, 27.2047915553, 7)
self.assertAlmostEqual(d.diffusivity, 4.25976905436e-07, 7)
d = DiffusionAnalyzer(d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip,
smoothed="constant", avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404055971202155, 7)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
# Can't average over 2000 steps because this is a 1000-step run.
self.assertRaises(ValueError, DiffusionAnalyzer,
d.structure, d.disp, d.specie, d.temperature,
d.time_step, d.step_skip, smoothed="constant",
avg_nsteps=2000)
d = DiffusionAnalyzer.from_structures(
list(d.get_drift_corrected_structures()),
d.specie, d.temperature, d.time_step,
d.step_skip, d.smoothed, avg_nsteps=100)
self.assertAlmostEqual(d.conductivity, 47.404055971202155, 7)
self.assertAlmostEqual(d.diffusivity, 7.4226016496716148e-07, 7)
