From Walking to Tunneling: An Investigation of Generalized Pilot-Wave Dynamics

TL;DR

This paper combines experimental and theoretical methods to analyze how millimetric walking droplets tunnel in complex three-dimensional cavities, introducing a new formalism for accurate simulation of their dynamics and tunneling probabilities.

Contribution

It introduces a generalized Dirichlet-to-Neumann operator framework for modeling droplet tunneling in intricate 3D topographies, enhancing simulation accuracy.

Findings

Successful experimental demonstration of droplet tunneling in complex geometries.

Development of a high-fidelity numerical simulation method for tunneling probabilities.

Insights into many-droplet interactions during tunneling processes.

Abstract

We investigate the ability of millimetric walking droplets to tunnel between spatially-structured cavities. By synthesizing experimental and theoretical analysis, we provide a comprehensive framework for droplet tunneling mechanics in three spatial dimensions. We define a generalized Dirichlet-to-Neumann operator that enables explicit characterization of droplet and wave-field dynamics under highly intricate variable-topography systems. This formalism enables a reduced, three-dimensional description of the pilot-wave field, facilitating high-fidelity numerical simulations of tunneling probabilities and long-time macroscopic dynamics with significantly improved accuracy over existing quasi-two-dimensional models. Moreover, we demonstrate experimental droplet tunneling in complex cavity geometries and discuss many-droplet coupling in the context of tunneling observations.