Shell-Shaped Quantum Droplet in a Three-Component Ultracold Bose Gas

TL;DR

This paper introduces a self-bound, shell-shaped Bose-Einstein condensate formed by a three-component ultracold gas, demonstrating a new curved quantum droplet structure without external trapping, and exploring its unique properties and excitations.

Contribution

It proposes a novel self-bound shell-shaped BEC in a three-component system, extending quantum droplets from flat to curved geometries and analyzing its properties.

Findings

Shell structure modifies core density significantly.

Unique collective excitations reveal core-shell correlations.

Realistic $^{23}$Na-$^{39}$K-$^{41}$K mixture demonstrates feasibility.

Abstract

Shell-shaped Bose-Einstein condensate (BEC) is a typical quantum system in curved geometry. Here we propose a new type of shell-shaped BEC with self-bound character, thereby liberating it from stringent conditions such as microgravity or fine-tuned trap. Specifically, we consider a three-component (1,2,3) ultracold Bose gas where (1,2) and (2,3) both form quantum droplets. The two droplets are mutually immiscible due to strong 1-3 repulsion, while still linked by component-2 to form a globally self-bound object. The outer droplet then naturally develops a shell structure without any trapping potential. It is shown that the shell structure can significantly modify the equilibrium density of the core, and lead to unique collective excitations highlighting the core-shell correlation. All results have been demonstrated in a realistic $^{23}$Na-$^{39}$K-$^{41}$K mixture. By extending quantum droplets from flat to curved geometries, this work paves the way for future exploring the interplay of quantum fluctuations and non-trivial real-space topologies in ultracold gases.