Interface pinning: Difference between revisions

Revision as of 11:51, 16 October 2024

Interface pinning^[1] is used to determine the melting point from a molecular-dynamics simulation of the interface between a liquid and a solid phase. The typical behavior of such a simulation is to freeze or melt, while the interface is pinned with a bias potential. This potential applies an energy penalty for deviations from the desired two-phase system. It is preferred simulating above the melting point because the bias potential prevents melting better than freezing.

The Steinhardt-Nelson^[2] order parameter $Q_6$ discriminates between the solid and the liquid phase. With the bias potential

U_\text{bias}(\mathbf{R}) = \frac\kappa2 \left(Q_6(\mathbf{R}) - A\right)^2

penalizes differences between the order parameter for the current configuration $Q_6({\mathbf{R}})$ and the one for the desired interface $A$ . $\kappa$ is an adjustable parameter determining the strength of the pinning.

Under the action of the bias potential, the system equilibrates to the desired two-phase configuration. An important observable is the difference between the average order parameter $\langle Q_6\rangle$ in equilibrium and the desired order parameter $A$ . This difference relates to the the chemical potentials of the solid $\mu_\text{solid}$ and the liquid $\mu_\text{liquid}$ phase

{\displaystyle N(\mu_\text{solid} - \mu_\text{liquid}) = \kappa (Q_{6,\text{solid}} - Q_{6,\text{liquid}})(\langle Q_6 \rangle - A) }

where $N$ is the number of atoms in the simulation.

Computing the forces requires a differentiable $Q_6(\mathbf{R})$ . In the VASP implementation a smooth fading function $w(r)$ is used to weight each pair of atoms at distance $r$ for the calculation of the $Q_6(\mathbf{R},w)$ order parameter. This fading function is given as

{\displaystyle w(r) = \left\{ \begin{array}{cl} 1 &\textrm{for} \,\, r\leq n \\ \frac{(f^2 - r^2)^2 (f^2 - 3n^2 + 2r^2)}{(f^2 - n^2)^3} &\textrm{for} \,\, n<r<f \\ 0 &\textrm{for} \,\,f\leq r \end{array}\right. }

Here $n$ and $f$ are the near- and far-fading distances, respectively. The radial distribution function $g(r)$ of the crystal phase yields a good choice for the fading range. To prevent spurious stress, $g(r)$ should be small where the derivative of $w(r)$ is large. Set the near fading distance $n$ to the distance where $g(r)$ goes below 1 after the first peak. Set the far fading distance $f$ to the distance where $g(r)$ goes above 1 again before the second peak.

References

[pedersen:prb:13-1] U. R. Pedersen, F. Hummel, G. Kresse, G. Kahl, and C. Dellago, Phys. Rev. B 88, 094101 (2013).

[steinhardt:prb:83-2] P. J. Steinhardt, D. R. Nelson, and M. Ronchetti, Phys. Rev. B 28, 784 (1983).

[1]

[2]

Revision as of 11:47, 16 October 2024 (view source) Karsai (talk \| contribs) (Removed redirect to Category:Interface pinning) Tag: Removed redirect ← Older edit		Revision as of 11:51, 16 October 2024 (view source) Karsai (talk \| contribs) (→‎References) Newer edit →
Line 48:		Line 48:
	----		----

	[[Category:VASP\|Interface pinning]][[Category:~~Molecular~~ dynamics]]		[[Category:VASP\|Interface pinning]][[Category:Advanced molecular-dynamics sampling]]