ML LCOUPLE: Difference between revisions
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</math> | </math> | ||
where <math>N_{a}</math> denotes the number of atoms and <math> U_{i,\mathbf{atom}}</math> is an atomic reference energy for a single non interacting atom. The first term in the equation describes the potential energy and the second and third term describe the potential energy of an atom <math>i</math>. The index <math>M</math> denotes the atoms whose interaction is controlled by a coupling parameter. | where <math>N_{a}</math> denotes the number of atoms and <math> U_{i,\mathbf{atom}}</math> is an atomic reference energy for a single non interacting atom. The first term in the equation describes the potential energy and the second and third term describe the potential energy of an atom <math>i</math>. The index <math>M</math> denotes the atoms whose interaction is controlled by a coupling parameter. The interaction of the atoms are controlled by scaling the contributions to the atom density via the coupling parameter | ||
<math> | |||
\rho (\mathbf{r},\lambda) = \sum\limits_{j\notin M} f_{\mathrm{cut}} \left( \left| \mathbf{r}_{j} - \mathbf{r}_{i} \right| \right) g \left[ \mathbf{r} - \left( \mathbf{r}_{j} - \mathbf{r}_{i} \right) \right] + \lambda \sum\limits_{j\in M} f_{\mathrm{cut}} | |||
</math> | |||
Further details on the implementation can be found in reference {{cite|jinnouchiti:prb:2020}}. | Further details on the implementation can be found in reference {{cite|jinnouchiti:prb:2020}}. | ||
For thermodynamic integration the following parameters have to be set: | |||
*{{TAG|ML_FF_LCOUPLE_MB}}=''.TRUE.'' | |||
*The number of atoms for which a coupling parameter is introduced (<math>i \notin M </math>): {{TAG|ML_FF_NATOM_COUPLED_MB}}. | |||
*The list of atom indices that for that the coupling parameter | |||
== References == | == References == |
Revision as of 17:41, 8 June 2021
ML_FF_LCOUPLE_MB = [logical]
Default: ML_FF_LCOUPLE_MB = .FALSE.
Description: This tag specifies whether coupling parameters are used for the calculation of chemical potentials is used or not within the machine learning force field method.
In thermodynamic integration a coupling parameter is introduced to the Hamiltonian to smoothly switch between a "non-interacting" reference state and a "fully-interacting" state. The change of the free energy along this path is written as
Using machine learning force fields the Hamiltonian can be written as
where denotes the number of atoms and is an atomic reference energy for a single non interacting atom. The first term in the equation describes the potential energy and the second and third term describe the potential energy of an atom . The index denotes the atoms whose interaction is controlled by a coupling parameter. The interaction of the atoms are controlled by scaling the contributions to the atom density via the coupling parameter
Further details on the implementation can be found in reference [1].
For thermodynamic integration the following parameters have to be set:
- ML_FF_LCOUPLE_MB=.TRUE.
- The number of atoms for which a coupling parameter is introduced (): ML_FF_NATOM_COUPLED_MB.
- The list of atom indices that for that the coupling parameter
References
Related Tags and Sections
ML_FF_LMLFF, ML_FF_NATOM_COUPLED_MB, ML_FF_ICOUPLE_MB, ML_FF_RCOUPLE_MB