Te-2021-09-03-all-icsd

../../_images/pareto259.png

The current structure dataset comprises 25863 structures generated from unique ICSD prototype structures composed of single elements with zero oxidation state. A more detailed procedure is found in Phys. Rev. B 99, 214108 (2019). The procedure to estimate interatomic potentials from the dataset is found in Phys. Rev. B 99, 214108 (2019) and Phys. Rev. B 102, 174104 (2020).

Improvement from **-dataset-10000-all-icsd

  • More robust for structures with a small interatomic distance

  • More robust for structures with a large interatomic distance

  • More complex potential models are included.

  • MLPs are estimated without using DFT stress tensors.

  • MLPs are estimated by using small regression weights for energetically unstable structures.

Predictions using Pareto optimal MLPs

../../_images/prediction-ecoh-volume153.png

The cohesive energy and volume are obtained by performing a local structure optimization from the DFT equilibrium structure. In addition, the DFT equilibrium structure is obtained by optimizing a prototype structure included in ICSD, and the prototype is used as the structure legend in the figure. Therefore, the structure type of the converged structure is sometimes different from that shown in the legend even if the potential energy surface predicted by MLP is almost the same as the true one.

The other properties predicted by each Pareto optimal MLP are available from column Predictions in the following table.

Te-2021-09-03-all-icsd shows large prediction errors. They should be carefully used. Such an MLP is often accurate for reasonable structures, but it is not accurate for unrealistic structures.

Pareto optimals

Name

Time [ms] (1core/36cores)

RMSE [meV/atom]/[eV/A]

Predictions

Files

gtinv-110

0.362 / 0.030

26.651 / 0.1721

gtinv-125

0.537 / 0.037

23.408 / 0.1616

gtinv-250

0.716 / 0.056

17.163 / 0.1485

gtinv-265

0.983 / 0.070

11.954 / 0.1292

gtinv-330

1.834 / 0.118

10.212 / 0.1220

gtinv-220

1.890 / 0.117

9.4668 / 0.1180

predictions

mlp.lammps input log

gtinv-285

2.031 / 0.123

9.4190 / 0.1173

predictions

mlp.lammps input log

gtinv-261

2.341 / 0.142

8.6437 / 0.1160

predictions

mlp.lammps input log

gtinv-262

2.839 / 0.166

8.2339 / 0.1120

predictions

mlp.lammps input log

gtinv-343

2.986 / 0.131

8.1648 / 0.1062

predictions

mlp.lammps input log

gtinv-267

3.516 / 0.196

8.1088 / 0.1109

predictions

mlp.lammps input log

gtinv-357

3.742 / 0.166

7.8741 / 0.1039

predictions

mlp.lammps input log

gtinv-360

4.081 / 0.224

7.7463 / 0.1047

predictions

mlp.lammps input log

gtinv-344

4.588 / 0.248

7.5162 / 0.1027

predictions

mlp.lammps input log

gtinv-264

5.489 / 0.315

7.3235 / 0.1061

predictions

mlp.lammps input log

gtinv-347

5.540 / 0.290

6.7368 / 0.1022

predictions

mlp.lammps input log

gtinv-232

10.649 / 0.547

6.6803 / 0.1018

predictions

mlp.lammps input log

gtinv-223

13.159 / 0.653

6.5449 / 0.0983

predictions

mlp.lammps input log

gtinv-288

13.824 / 0.659

6.5292 / 0.0980

predictions

mlp.lammps input log

gtinv-224

14.066 / 0.687

6.2395 / 0.0962

predictions

mlp.lammps input log

gtinv-289

14.825 / 0.712

6.2311 / 0.0960

predictions

mlp.lammps input log

gtinv-228

16.624 / 0.807

6.1489 / 0.0973

predictions

mlp.lammps input log

gtinv-294

17.107 / 0.825

6.0463 / 0.0954

predictions

mlp.lammps input log

gtinv-229

17.857 / 0.829

6.0349 / 0.0955

predictions

mlp.lammps input log

gtinv-234

21.888 / 1.017

6.0133 / 0.0958

predictions

mlp.lammps input log

Column “Time” shows the time required to compute the energy and forces for 1 MD step and 1 atom, which is estimated from a simulation of 10 runs for a structure with 284 atoms using a workstation with Intel(R) Xeon(R) CPU E5-2695 v4 @ 2.10GHz. Note that the MLPs should be carefully used for extreme structures. The MLPs often return meaningless values for them.

  • All Pareto optimal MLPs are available here.