# Rotational instability in superlubric joints

**Authors:** Cangyu Qu, Songlin Shi, Quanshui Zheng

arXiv: 1903.06512 · 2019-06-26

## TL;DR

This paper uncovers a new type of mechanical instability in superlubric joints driven by surface energies, characterized by a sudden transition from translation to rotation during sliding, with implications for designing superlubricity devices.

## Contribution

It introduces a novel instability mechanism in superlubric joints controlled by surface energies, supported by theoretical and experimental analysis, applicable across various scales.

## Key findings

- Observed unrotational sliding followed by sudden rotation transition.
- Theoretical model aligns with experimental results.
- Instability mechanism is general for ultralow friction joints.

## Abstract

Surface and interfacial energies play important roles in a number of instability phenomena in liquids and soft matters, but are rare to play a similar role in solids. Here we report a new type of mechanical instabilities that are controlled by surface and interfacial energies and are valid for a large class of materials, in particular two-dimensional layered materials. When sliding a top flake cleaved from a square microscale graphite mesa by using a probe acted on the flake through a point contact, we observed that the flake moved unrotationally for a certain distance before it suddenly transferred to a rotating-moving state. The theoretical analysis that agrees well with the experimental observation reveals that this mechanical instability is an interesting effect of the structural superlubricity (a state of nearly zero friction). Our further analysis shows that this type of instability holds generally for various sliding joints on different scales, as long as the friction is ultralow. Thus, the uncovered mechanism provides useful knowledge for manipulating and controlling all these sliding joints, and can guide design of future structural superlubricity based devices.

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Source: https://tomesphere.com/paper/1903.06512