Friction on incommensurate substrates: Role of anharmonicity and defects

TL;DR

This study uses molecular dynamics simulations to explore how anharmonicity and defects influence friction on incommensurate substrates, revealing that these factors generally increase friction by promoting full thermalization of vibrational modes.

Contribution

It demonstrates how anharmonicity and defects alter vibrational mode thermalization, significantly impacting sliding friction in incommensurate systems, which was not fully understood before.

Findings

Partial thermalization occurs at specific velocities without anharmonicity.

Anharmonicity and defects lead to full thermalization and higher friction.

Controlling edge properties affects sliding distance and thermalization.

Abstract

We present Molecular Dynamics simulations of one- and two-dimensional bead-spring models sliding on incommensurate substrates. We investigate how sliding friction is affected by interaction anharmonicity and structural defects. In their absence, we confirm earlier findings, namely, that at special resonance sliding velocities, friction is maximal. When sliding off-resonance, partially thermalized states are possible, whereby only a small number of vibrational modes becomes excited, but whose kinetic energies are already Maxwell-Boltzmann distributed. Anharmonicity and defects typically destroy partial thermalization, and instead lead to full thermalization, implying much higher friction. For sliders with periodic boundaries, thermalization begins with vibrational modes whose spatial modulation is compatible with the incommensurate lattice. For a disc-shaped slider, modes corresponding to modulations compatible with the slider radius are initially the most dominant. By tuning the mechanical properties of the slider's edge, this effect can be controlled, resulting in significant changes in the sliding distance covered.