Dependency of Sliding Friction for Two Dimensional Systems on Electronegativity

TL;DR

This study reveals that electronegativity differences significantly influence sliding friction in 2D monolayer systems, with a universal linear scaling law for polar paths, offering insights for nanoscale device design.

Contribution

It demonstrates the impact of electronegativity on friction in 2D materials and establishes a universal linear relationship for polar sliding paths.

Findings

Friction depends strongly on electronegativity difference.

Friction along nonpolar paths is nearly constant across materials.

A universal linear scaling law relates friction to electronegativity difference.

Abstract

We study the role of electronegativity in sliding friction for five different two dimensional (2D) monolayer systems using density functional theory (DFT) with van der Waals (vdW) corrections. We show that the friction between the commensurate 2D layered systems depends strongly on the electronegativity difference of the involved atoms. All the 2D layered structures exhibit almost the same magnitude of friction force when sliding along the nonpolar path, independent of the material and the surface structures. In contrast, for sliding friction along the polar path, the friction force obeys a universal linear scaling law as a function of the electronegativity difference of its constituent atoms. Further analyses demonstrate that atomic dipoles in the 2D monolayers induced by the electronegativity difference enhance the corrugation of charge distribution and increase the sliding barrier accordingly. Our studies reveal that electronegativity plays an important role in friction of low dimensional systems, and will provide a strategy for designing nanoscale devices further.