# Surface Melting and Breakup of Metal Nanowires: Theory and Molecular   Dynamics Simulations

**Authors:** Kannan M. Ridings, Thomas S. Aldershof, Shaun C. Hendy

arXiv: 1812.05724 · 2019-03-27

## TL;DR

This paper combines theoretical modeling and molecular dynamics simulations to study surface melting and breakup of metal nanowires, revealing conditions for surface melting and differences between nickel and aluminium behaviors.

## Contribution

It introduces a phenomenological Landau model for surface melting and validates it with molecular dynamics simulations on nickel and aluminium nanowires, highlighting anisotropic and incomplete melting phenomena.

## Key findings

- Surface melting precedes bulk melting when the spreading parameter is positive.
- Nickel nanowires exhibit anisotropic and then uniform surface melting leading to breakup.
- Aluminium nanowires show partial wetting and incomplete melting of certain facets.

## Abstract

We consider the surface melting of metal nanowires by solving a phenomenological two-parabola Landau model and by conducting molecular dynamics simulations of nickel and aluminium nanowires. The model suggests that surface melting will precede bulk melting when the spreading parameter $\Delta \gamma$ for the melt in contact with the solid surface is positive (i.e. if the melt wets or partially wets the surface) and the wire is sufficiently thick, as is the case for planar surfaces and sufficiently large nanoparticles. Surface melting does not occur if $\Delta \gamma$ is negative. We test this model, which assumes the surface energies of the wire are isotropic, using molecular dynamics simulations. For nickel, we observe the onset of anisotropic surface melting associated with each of the two surface facets present, but this gives way to uniform surface melting and the solid melts radially until the solid core eventually breaks up. For aluminium, while we observe complete surface melting of one facet, the lowest energy surface remains partially dry even up to the point where the melt completely penetrates the solid core.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1812.05724/full.md

## References

33 references — full list in the complete paper: https://tomesphere.com/paper/1812.05724/full.md

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Source: https://tomesphere.com/paper/1812.05724