Category:Machine-learned force fields: Difference between revisions
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'''Machine-learned force fields''' from ab-initio [[:Category:Molecular dynamics|molecular dynamics]] (MD) allow capturing the underlying physics from first principles and still reach long simulation times relatively cheaply. Generally, an ab-initio MD step is computationally expensive due to the [[:Category:Electronic minimization|quantum-mechanical treatment of the electrons]], e.g., within density-functional theory (DFT). In fully classical MD calculations, '''force fields''' are used to evaluate the force acting on each atom instead of DFT. These interatomic potentials are traditionally based on experimental observation and empirical inclusion of known forces, such as the van-der-Waals force, electrostatic charges, etc. Therefore the quality of the force field depends on how well interactions in the specific system | '''Machine-learned force fields''' from ab-initio [[:Category:Molecular dynamics|molecular dynamics]] (MD) allow capturing the underlying physics from first principles and still reach long simulation times relatively cheaply. Generally, an ab-initio MD step is computationally expensive due to the [[:Category:Electronic minimization|quantum-mechanical treatment of the electrons]], e.g., within density-functional theory (DFT). In fully classical MD calculations, '''force fields''' are used to evaluate the force acting on each atom instead of DFT. These interatomic potentials are traditionally based on experimental observation and empirical inclusion of known forces, such as the van-der-Waals force, electrostatic charges, etc. Therefore, the quality of the force field depends on how well interactions in the specific system are known. | ||
VASP offers '''machine learning force fields on-the-fly''' to overcome these two issues. Namely, the high computational cost required for ab-initio MD and the empirical knowledge necessary to construct a force field the traditional way. To learn more about on-the-fly machine learning read about the [[Machine learning force field: Theory|theory of on-the-fly machine learning force fields]] or about the [[Machine learning force field calculations: Basics| setup of a basic calculation]]! Also, check out the description on [[Best practices for machine-learned force fields|best practices on how to construct, test, and retrain force fields]], as well as the [https://www.vasp.at/tutorials/latest/md/part2/ basic tutorial that provides hands-on experience for silicon] and this tutorial: {{TAG|Liquid Si - MLFF}}. | VASP offers '''machine learning force fields on-the-fly''' to overcome these two issues. Namely, the high computational cost required for ab-initio MD and the empirical knowledge necessary to construct a force field the traditional way. To learn more about on-the-fly machine learning read about the [[Machine learning force field: Theory|theory of on-the-fly machine learning force fields]] or about the [[Machine learning force field calculations: Basics| setup of a basic calculation]]! Also, check out the description on [[Best practices for machine-learned force fields|best practices on how to construct, test, and retrain force fields]], as well as the [https://www.vasp.at/tutorials/latest/md/part2/ basic tutorial that provides hands-on experience for silicon] and this tutorial: {{TAG|Liquid Si - MLFF}}. |
Revision as of 09:28, 28 April 2022
Machine-learned force fields from ab-initio molecular dynamics (MD) allow capturing the underlying physics from first principles and still reach long simulation times relatively cheaply. Generally, an ab-initio MD step is computationally expensive due to the quantum-mechanical treatment of the electrons, e.g., within density-functional theory (DFT). In fully classical MD calculations, force fields are used to evaluate the force acting on each atom instead of DFT. These interatomic potentials are traditionally based on experimental observation and empirical inclusion of known forces, such as the van-der-Waals force, electrostatic charges, etc. Therefore, the quality of the force field depends on how well interactions in the specific system are known.
VASP offers machine learning force fields on-the-fly to overcome these two issues. Namely, the high computational cost required for ab-initio MD and the empirical knowledge necessary to construct a force field the traditional way. To learn more about on-the-fly machine learning read about the theory of on-the-fly machine learning force fields or about the setup of a basic calculation! Also, check out the description on best practices on how to construct, test, and retrain force fields, as well as the basic tutorial that provides hands-on experience for silicon and this tutorial: Liquid Si - MLFF.
Theory
VASP uses a Bayesian-learning algorithm for on-the-fly machine learning. The total energy and forces are predicted based on the machine-learned force field at each time step of the MD simulation. If the Bayesian error exceeds a certain threshold an ab-initio calculation is performed, where electrons are treated quantum mechanically. Subsequently, descriptors of so-called local configurations (i.e., the radial and angular distribution of neighboring atoms around a given ion) are selected from the structure and the force field is retrained on the energy of the ab-initio calculation.
For details on the algorithm, check out the theory article about machine learning force fields.
How to
All related INCAR tags and input/output files begin with the prefix ML_. To learn about machine learning force fields, visit:
- Machine learning force field calculations: Basics.
- Best practices for machine-learned force fields include how to construct, test, and retrain force fields.
- Basic tutorial that provides hands-on experience for silicon.
- Liquid Si - MLFF.
Input
- Depending on whether the calculation is training, retraining, or applying the force field (see ML_ISTART), VASP may require the following input files in addition to the usual input files (INCAR, POSCAR, etc.):
Output
- The machine-learning–force-field method generates the following output files:
- ML_LOGFILE Main output file.
- ML_ABN Generated ab-initio training data. It is used as ML_AB file to restart a calculation.
- ML_REG Summary of regression results.
- ML_HIS Summary of the histogram data.
- ML_FFN Force-field parameters. It is used as ML_FF file to restart a calculation.
- ML_EATOM Local atomic energies.
- ML_HEAT Local heat flux.
Pages in category "Machine-learned force fields"
The following 71 pages are in this category, out of 71 total.
M
- Machine learning force field calculations: Basics
- Machine learning force field: Theory
- ML AB
- ML ABN
- ML AFILT2
- ML CALGO
- ML CDOUB
- ML CSIG
- ML CSLOPE
- ML CTIFOR
- ML CX
- ML DESC TYPE
- ML EATOM
- ML EATOM REF
- ML EPS LOW
- ML EPS REG
- ML FF
- ML FFN
- ML HEAT
- ML HIS
- ML IAFILT2
- ML IALGO LINREG
- ML ICOUPLE
- ML ICRITERIA
- ML IERR
- ML IREG
- ML ISCALE TOTEN
- ML ISTART
- ML IWEIGHT
- ML LAFILT2
- ML LBASIS DISCARD
- ML LCOUPLE
- ML LEATOM
- ML LERR
- ML LFAST
- ML LHEAT
- ML LMAX2
- ML LMLFF
- ML LOGFILE
- ML LSPARSDES
- ML LUSE NAMES
- ML MB
- ML MB MIN
- ML MCONF
- ML MCONF NEW
- ML MHIS
- ML MODE
- ML MRB1
- ML MRB2
- ML NATOM COUPLED
- ML NHYP
- ML NMDINT
- ML NRANK SPARSDES
- ML OUTBLOCK
- ML OUTPUT MODE
- ML RCOUPLE
- ML RCUT1
- ML RCUT2
- ML RDES SPARSDES
- ML REG
- ML SCLC CTIFOR
- ML SIGV0
- ML SIGW0
- ML SION1
- ML SION2
- ML W1
- ML WTIFOR
- ML WTOTEN
- ML WTSIF