Observation of quantum friction in solid 4He

TL;DR

This study provides experimental evidence of quantum phonon friction between solid helium-4 crystallites, confirming theoretical predictions about quantum friction mechanisms at low temperatures.

Contribution

First experimental observation of quantum phonon friction in solid helium-4, validating theoretical models of quantum friction at the microscopic level.

Findings

Friction force measured aligns with quantum phonon friction theory

Quantum friction persists even in superlubricity conditions

Experimental data matches theoretical predictions for quantum excitations

Abstract

Classical sliding friction is dominated by the slip-stick mechanism, where contacts between two bodies are alternately formed and sheared as the bodies move past each other. When the interface between two bodies is perfectly smooth, classical friction goes to zero, a state called superlubricity. In this limit, much weaker mechanisms, called quantum friction are predicted. These mechanisms are based on an exchange of elementary excitations between two bodies moving relatively to each other. For the friction to be called quantum, the excitations must arise from the quantum mechanical description of the bodies. Photons and phonons are such excitations. Friction results from an irreversible momentum transfer from these excitations to the bodies, affecting their motion. We measured the friction force between crystallites of solid 4He moving relative to each other at low temperatures. Our data are in excellent agreement with the concept of quantum phonon friction.