The pilot-wave dynamics of walking droplets

Author(s)

Harris, Daniel Martin; Bush, John W. M.

Abstract

A millimetric droplet can be induced to bounce on the surface of a fluid bath by vibrating the bath near the droplet's resonant frequency (Figure 1(a) ). [superscript 1–3] The localized field of Faraday waves excited by the bouncing droplet can cause it to propel itself laterally across the surface, moving in resonance with its guiding wave field (Figure 1(b) ). [superscript 4,5] These walking droplets, or “walkers,” generally move in a straight line at constant speed; however, they can be diverted through interaction with boundaries or external forces. This hydrodynamic system represents a macroscopic realization of the pilot-wave theory of quantum dynamics proposed by Louis de Broglie, according to which microscopic particles are propelled through a resonant interaction with a wave field generated by the particle's internal vibration. [superscript 6] Coincidentally, it exhibits many behaviors once thought to be exclusive to the microscopic quantum realm, including single-particle diffraction, [superscript 7] tunneling, [superscript 8] quantized orbits, [superscript 9] and orbital-level splitting. [superscript 10]

Date issued

2013-09

URI

http://hdl.handle.net/1721.1/92913

Department

Massachusetts Institute of Technology. Department of Mathematics

Journal

Physics of Fluids

Publisher

American Institute of Physics (AIP)

Citation

Harris, Daniel M., and John W. M. Bush. “The Pilot-Wave Dynamics of Walking Droplets.” Physics of Fluids 25, no. 9 (2013): 091112.

Version: Author's final manuscript

ISSN

10706631

1089-7666