Low-Temperature Friction of Suspended Graphene: Negative friction?

TL;DR

This study uses molecular dynamics to explore how suspended graphene exhibits negative friction at low temperatures, revealing a novel oscillation-based energy dissipation mechanism that impacts nanoscale friction behavior.

Contribution

It uncovers a temperature-dependent negative friction phenomenon in suspended graphene and links it to spontaneous oscillations influencing nanoscale energy dissipation.

Findings

Negative friction observed at liquid-helium temperature

Spontaneous lateral oscillations of graphene at low temperature

Oscillations contribute to a hidden energy dissipation mechanism

Abstract

Using molecular dynamics simulations, we probe a suspended graphene layer by a diamond-like-carbon tip at various temperatures. The force acting on the tip in the sliding direction is measured to be negative at liquid-helium temperature. This negative force is found to be associated with a spontaneous lateral oscillation of the suspended graphene in favor of a low interface potential corrugation. Our hypothesis is that, at low temperature, this oscillation induces an important hidden contribution to the friction force in the lateral direction. This functions as a particular energy dissipation mechanism at nanoscale.