Minimal Quantization Model in Pilot-Wave Hydrodynamics

Austin M. Blitstein, Rodolfo R. Rosales, and Pedro J. Sáenz

Phys. Rev. Lett. 132, 104003 – Published 8 March 2024

Abstract

Investigating how classical systems may manifest dynamics analogous to those of quantum systems is a broad subject of fundamental interest. Walking droplets, which self-propel through a resonant interaction with their own wave field, provide a unique macroscopic realization of wave-particle duality that exhibits behaviors previously thought exclusive to quantum particles. Despite significant efforts, elucidating the precise origin and form of the wave-mediated forces responsible for the walker’s quantumlike behavior remained elusive. Here, we demonstrate that, owing to wave interference, the force responsible for orbital quantization originates from waves excited near stationary points on the walker’s past trajectory. Moreover, we derive a minimal model with the essential ingredients to capture quantized orbital dynamics, including quasiperiodic and chaotic orbits. Notably, this minimal model provides an explicit distinction between local forces, which account for the walker’s preferred speed and wave-induced added mass, and spatiotemporal nonlocal forces responsible for quantization. The quantization mechanism revealed here is generic, and will thus play a role in other hydrodynamic quantum analogs.

Received 25 June 2023
Revised 6 October 2023
Accepted 31 January 2024

DOI:https://doi.org/10.1103/PhysRevLett.132.104003

Physics Subject Headings (PhySH)

Capillary waves Drop & bubble phenomena Faraday waves Low-dimensional models Surface gravity waves Surface tension effects

Water

Fluid DynamicsPolymers & Soft Matter

Authors & Affiliations

Austin M. Blitstein ¹, Rodolfo R. Rosales ², and Pedro J. Sáenz ^1,*

¹Department of Mathematics, University of North Carolina, Chapel Hill, North Carolina 27599, USA
²Department of Mathematics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA

^*saenz@unc.edu

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Vol. 132, Iss. 10 — 8 March 2024

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Images

Figure 1
(a) Oblique view of a walking droplet, or walker, self-propelled by its wave field as seen in experiments. (b)–(e) Top view of the wave field of a walker (green disk) traveling clockwise along a circular orbit of radius $r$ with orbital frequency $ω$ in a bath rotating counterclockwise with angular frequency $Ω$ . The full wave field in (b) is generated by the waves excited by the drop at each bounce along its past trajectory. We can thus decompose the wave field [shown in (b)] according to wave contributions [shown in (c)–(e)] produced by the walker along different portions of the past trajectory (highlighted in bright green). Waves excited in the vicinity of stationary points interfere constructively at the droplet’s location (c), causing orbital quantization, while those produced elsewhere interfere destructively at the droplet’s location (d), except for the waves excited in the walker’s recent past (e). (f) Quasicircular orbit illustrating the emergence of stationary points at different locations. The pilot-wave force $F_{W}$ is approximated by the sum of nonlocal forces $F_{Q}$ emanating from stationary points (blue) and a local boost force $F_{B}$ . Stationary points near the droplet (red) may be neglected on account of the wave force being small. (Photo copyright: Abel J. Abraham).
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Figure 2
Orbital solutions to the MQM and stroboscopic model. Memory increases from left to right, with (a) $γ / γ_{F} = 0.922$ , (b) $γ / γ_{F} = 0.954$ , (c) $γ / γ_{F} = 0.971$ , and (d) $γ / γ_{F} = 0.985$ . Excellent agreement is observed except for a few small discrepancies shown with insets in (c),(d), which have a negligible effect in the orbital quantization. Black dashed lines correspond to $r_{n} = (n + 3 / 4) λ_{F} / 2$ .
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Figure 3
Among previously known orbits, the MQM captures (a) circular $(r / λ_{F}, γ / γ_{F}) = (0.9, 0.95)$ , (b) jump-up (0.55, 0.94), (c) jump-down (0.8, 0.97), (d) $2 ω$ -wobble (0.85, 0.955), (e) $3 ω$ -wobble (0.94, 0.9745), and (f) quasiperiodic orbits (0.893, 0.966). Walker’s were initialized in circular orbits of radius $r$ (red).
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Figure 4
Dependence of mean orbital radius $r$ on bath rotation frequency for walkers evolved with the MQM and stroboscopic model at $γ / γ_{F} = 0.954$ . Error bars indicate the maximum radial deviation from the mean. The black curve denotes all circular orbit solutions, as in Fig. 2. Both models predict the same plateaus.
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Figure 5
Statistical quantization at $γ / γ_{F} = 0.980$ . (a) Forces on the droplet for a chaotic trajectory generated by the MQM due to an intricate interplay between stationary points. Radial statistics for the (b) stroboscopic model, and (c) MQM. Each vertical line is a histogram of the radius of curvature for fixed bath rotation frequency, as seen in (d) and (e). Good agreement is found for low bath rotation frequency (d).
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