Hydrodynamic nuclear analogs with active wave-particle clusters

Abstract: Active particles are non-equilibrium entities that uptake energy and convert it into self-propulsion. A dynamically rich class of active particles having features of wave-particle coupling and memory are walking/superwalking droplets. Such classical, active wave-particle entities (WPEs) have been shown to exhibit hydrodynamic analogs of many single-particle quantum systems. We numerically investigate the dynamics of several WPEs and find that they self-organize into a bound cluster, akin to a nucleus. This active cluster exhibits various modes of collective excitations as the memory of the system is increased. Dynamically distinct excitation modes create a common time-averaged collective potential indicating an analogy with the bag model of a nucleus. At high memory, the active cluster can destabilize and eject WPEs whose decay statistics follow exponential laws analogous to radioactive nuclear decay. Hydrodynamic nuclear analogs open up new directions to pursue, both experimentally and numerically, within the nascent field of hydrodynamic quantum analogs.