Phonon controlled mechanical memory via pinning and depinning of transition waves

TL;DR

This paper introduces a universal phonon-based method to control transition wave pinning and depinning in multistable mechanical metamaterials, enabling scalable and robust mechanical memory and computing.

Contribution

It presents a novel phonon-resonance strategy for controlling kink transitions in mechanical metamaterials, inspired by solid-state physics interactions.

Findings

Phonon-beating envelope resonantly couples with kink modes.

Efficient energy transfer over defect barriers.

Enables scalable mechanical memory applications.

Abstract

Multistable mechanical metamaterials enable programmable transitions between discrete stable states through propagating kink transition waves (TWs). Yet controlling these kinks typically requires local actuation or high-energy deformation, limiting scalability. Here we demonstrate a universal strategy for pinning and depinning TWs using local defects and boundary phonon excitations. Inspired by phonon-dislocation interactions in crystalline solids, we use pairs of phonons that form a beating envelope resonant with the pinned kink's translational mode, which lies within a phononic band gap. This resonant coupling efficiently transfers energy to the kink, allowing it to overcome defect barriers and propagate across impurities. The proposed mechanism enables application of these systems as information processing units in mechanical computing, namely as scalable and more robust mechanical memory.