Litcius/Paper detail

Angular Momentum in Rotating Superfluid Droplets

Sean M. O. O’Connell, Rico Mayro P. Tanyag, Deepak Verma, Charles Bernando, Weiwu Pang, Camila Bacellar, Catherine A. Saladrigas, Johannes Mahl, Benjamin W. Toulson, Yoshiaki Kumagai, Peter Walter, Francesco Ancilotto, M. Barranco, M. Pí, Christoph Bostedt, Oliver Geßner, Andrey F. Vilesov

2020Physical Review Letters42 citationsDOIOpen Access PDF

Abstract

The angular momentum of rotating superfluid droplets originates from quantized vortices and capillary waves, the interplay between which remains to be uncovered. Here, the rotation of isolated submicrometer superfluid ^{4}He droplets is studied by ultrafast x-ray diffraction using a free electron laser. The diffraction patterns provide simultaneous access to the morphology of the droplets and the vortex arrays they host. In capsule-shaped droplets, vortices form a distorted triangular lattice, whereas they arrange along elliptical contours in ellipsoidal droplets. The combined action of vortices and capillary waves results in droplet shapes close to those of classical droplets rotating with the same angular velocity. The findings are corroborated by density functional theory calculations describing the velocity fields and shape deformations of a rotating superfluid cylinder.

Topics & Concepts

SuperfluidityAngular momentumPhysicsTotal angular momentum quantum numberMomentum (technical analysis)Classical mechanicsQuantum mechanicsFinanceEconomicsQuantum, superfluid, helium dynamicsCold Atom Physics and Bose-Einstein CondensatesAtomic and Subatomic Physics Research