Persistent nonlinear phase-locking and non-monotonic energy dissipation in micromechanical resonators

TL;DR

This study experimentally uncovers persistent nonlinear phase-locking in micromechanical resonators, revealing its crucial role in transient dynamics and energy exchange, with implications for diverse physical systems.

Contribution

It demonstrates the existence of persistent phase-locked states at internal resonances and provides a quantitative model for their role in nonlinear resonator dynamics.

Findings

Persistent phase-locking occurs at internal resonances.

The model explains energy exchange and non-monotonic energy evolution.

System relaxation pathways depend on initial phase.

Abstract

Many nonlinear systems are described by eigenmodes with amplitude-dependent frequencies, interacting strongly whenever the frequencies become commensurate at internal resonances. Fast energy exchange via the resonances holds the key to rich dynamical behavior, such as time-varying relaxation rates and signatures of nonergodicity in thermal equilibrium, revealed in the recent experimental and theoretical studies of micro and nanomechanical resonators. However, a universal yet intuitive physical description for these diverse and sometimes contradictory experimental observations remains elusive. Here we experimentally reveal persistent nonlinear phase-locked states occurring at internal resonances and demonstrate that they are essential for understanding the transient dynamics of nonlinear systems with coupled eigenmodes. The measured dynamics of a fully observable micromechanical resonator system are quantitatively described by the lower frequency mode entering, maintaining, and exiting a persistent phase-locked period tripling state generated by the nonlinear driving force exerted by the higher frequency mode. This model describes the observed phase-locked coherence times, the direction and magnitude of the energy exchange, and the resulting non-monotonic mode energy evolution. Depending on the initial relative phase, the system selects distinct relaxation pathways, either entering or bypassing the locked state. The described persistent phase-locking is not limited to particular frequency fractions or types of nonlinearities and may advance nonlinear resonator systems engineering across physical domains, including photonics as well as nanomechanics.