Non-resonant effects in pilot-wave hydrodynamics

TL;DR

This paper develops a theoretical model of pilot-wave hydrodynamics that relaxes resonance assumptions, explaining complex droplet behaviors like swaying, intermittent walking, and chaotic oscillations observed in experiments.

Contribution

It introduces a non-resonant model capturing vertical and horizontal droplet dynamics, providing new insights into previously poorly understood phenomena in pilot-wave hydrodynamics.

Findings

Explains swaying and intermittent walking behaviors.

Reveals degeneracy in vertical bouncing phases.

Highlights impact phase changes during chaotic motion.

Abstract

Pilot-wave hydrodynamics concerns the dynamics of 'walkers,' droplets walking on a vibrating bath, and has provided the basis for the burgeoning field of hydrodynamic quantum analogs. We here explore a theoretical model of pilot-wave hydrodynamics that relaxes the simplifying assumption of resonance between the droplet and its pilot wave, specifically the assumption of a fixed impact phase between the bouncing drop and its wave field. The model captures both the vertical and horizontal dynamics of the drop, allowing one to examine non-resonant effects for both free and constrained walkers. The model provides new rationale for a number of previously reported but poorly understood features of free walker motion in pilot-wave hydrodynamics, including colinear swaying at the onset of motion, intermittent walking, and chaotic speed oscillations, all of which are accompanied by sporadic changes in the impact phase of the bouncing drop. The model also highlights the degeneracy in the droplets' vertical dynamics, specifically, the possibility of two distinct bouncing phases and of switching between the two. Consideration of this degeneracy is critical to understanding the droplet dynamics and statistics emerging in confined geometries at high memory and the interaction of walking droplets with standing Faraday waves.