Wetting of quantum fluids: a route to free-standing shell-shaped quantum droplets

Abstract

We investigate wetting phenomena between self-bound quantum fluids in a three-component Bose mixture of 23Na, 39K, and 41K atoms. Within a density-functional approach including mean-field interactions and Lee-Huang-Yang quantum-fluctuation corrections, we consider two binary quantum liquids, formed by components (1,2) and (2,3), and study the adsorption of the softer (1,2) liquid on a stiffer (2,3) substrate. By tuning the interspecies scattering length a12, we show that the surface tension of the (1,2) liquid can be strongly varied, driving a transition from partial wetting to complete wetting of the (2,3) phase. The contact angle extracted from cylindrical-cap geometries decreases continuously with increasing a12 and vanishes near a critical value a12c= -42\,a0. In the complete-wetting regime, a finite amount of (1,2) liquid wraps around a spherical (2,3) droplet, producing a self-bound core-shell droplet without external confinement, whose component-1 density has a shell-like, hollow projection. We further show that such shell-shaped quantum droplets can sustain quantized vortical excitations. These results identify wetting as a route to engineering free-standing shell-shaped quantum liquids and suggest new possibilities for studying capillarity, topology, and superfluidity in multicomponent quantum droplets.