# Dissipation and plastic deformation in collisions between metallic   nanoparticles

**Authors:** William C. Tucker, Adrienne R. Dove, Patrick K. Schelling

arXiv: 1902.01250 · 2019-02-05

## TL;DR

This study uses molecular dynamics to analyze collisions between metallic nanoparticles, revealing significant dissipation, plastic deformation, and adhesion effects that challenge classical models like JKR.

## Contribution

It demonstrates the dominant role of atomic vibrations and plastic deformation in nanoparticle collisions, providing new scaling relations and insights beyond traditional adhesion models.

## Key findings

- Strong dissipation into atomic vibrations prevents rebound.
- Adhered nanoparticles develop a 'neck' increasing with velocity.
- Plastic deformation occurs at high stress levels during collisions.

## Abstract

Collisions between amorphous Fe nanoparticles were studied using molecular-dynamics simulation. For head-on collisions of nanoparticles with radii $R =$ 1.4 nm, $R =$ 5.2 nm, and $R =$ 11 nm, sticking was observed at all simulated velocities. The results were compared to the description provided by the JKR model. It was found that strong disagreement exists between the predictions of JKR and the results of the molecular-dynamics simulation due to the presence of additional dissipative processes which strengthen sticking behavior. First, it is demonstrated that very strong dissipation into atomic vibrations occurs during the collision. The dissipation is strong enough to prevent significant rebound of the nanoparticles. Additionally, the morphology of the adhered nanoparticles includes a ``neck'' that increases in radius with increasing collision velocity which results in amplified irreversibility and adhesion. Approximate calculation of the stress during the collision indicates that stress levels are well above typical yield stress values even for low velocity collisions, consistent with the observation of plastic deformation. Furthermore, it is shown that for nanoparticles with $R \leq$ 11 nm, the dominance of surface attraction results in large effective collision velocities and plastic deformation. By obtaining scaling relations for computed quantities, predictions are made for larger nanoparticles up to $R$ $\sim$ 1 $\mu$m. This work provides a new perspective on collisional dissipation and adhesion with an important connection to the modern understanding of tribology and friction.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1902.01250/full.md

## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1902.01250/full.md

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Source: https://tomesphere.com/paper/1902.01250