Quantum Lotka-Volterra dynamics

TL;DR

This paper demonstrates predator-prey dynamics using laser excitation and ionisation of Rydberg atoms, providing a physical realization of Lotka-Volterra models with potential applications in metrology and remote sensing.

Contribution

It introduces a novel physical system exhibiting predator-prey dynamics, bridging quantum atomic physics with classical non-linear models.

Findings

Laser excitation and ionisation produce predator-prey oscillations.

Comparison with Lotka-Volterra model confirms dynamic similarity.

Potential applications in plasma sensing and metrology.

Abstract

Physical systems that display competitive non-linear dynamics have played a key role in the development of mathematical models of Nature. Important examples include predator-prey models in ecology, biology, consumer-resource models in economics, and reaction-diffusion equations in chemical reactions. However, as real world systems are embedded in complex environments, where it is difficult or even impossible to control external parameters, quantitative comparison between measurements and simple models remains challenging. This motivates the search for competitive dynamics in isolated physical systems, with precise control. An ideal candidate is laser excitation in dilute atomic ensembles. For example, atoms in highly-excited Rydberg states display rich many-body dynamics including ergodicity breaking, synchronisation and time crystals. Here, we demonstrate predator-prey dynamics by laser excitation and ionisation of Rydberg atoms in a room temperature vapour cell. Ionisation of excited atoms produce electric fields that suppress further excitation. This starves the ionisation process of resource, giving rise to predator-prey dynamics. By comparing our results to the Lotka-Volterra model, we demonstrate that as well applications in non-linear dynamics, our experiment has applications in metrology, and remote sensing of localised plasmas.