Superfluids provide new insight into turbulence
Date:
February 17, 2022
Source:
University of Queensland
Summary:
Eddies in an exotic liquid known as a superfluid merge to form
large vortices, analogous to how cyclones form in the turbulent
atmosphere.
FULL STORY ========================================================================== Eddies in an exotic liquid known as a superfluid merge to form large
vortices, analogous to how cyclones form in the turbulent atmosphere.
==========================================================================
The new research, by a team from The University of Queensland, the
ARC Centre of Excellence for Engineered Quantum Systems (EQUS) and the
ARC Centre of Excellence in Future Low-Energy Electronics Technologies
(FLEET) will be important for emerging technological applications of superfluidity, such as precision sensing.
Lead author and theorist Dr Matt Reeves said the team's results
provide experimental validation of a 70-year-old theory -- a model for two-dimensional vortex equilibrium by Nobel Laureate Lars Onsager.
"Large, long-lived vortices like cyclones or Jupiter's Great Red Spot
often form out of turbulent fluid flows, such as the atmospheres of
planets," he said.
"Onsager's model explains the existence of these structures, but so far experiments have tended to conflict with the predictions," he said.
"A key complication is that most fluids are viscous, meaning they
resist flow.
========================================================================== "Superfluids, which have no viscosity, are therefore ideal candidates
to realise Onsager's model." Dr Tyler Neely, who led the experiments,
said the team studied the behaviour of vortices in a superfluid known
as a Bose-Einstein condensate, which is produced by cooling a gas of
rubidium atoms to extremely cold temperatures.
"We created a thin disk of the superfluid and then used lasers to inject vortices at carefully specified locations," he said.
"The vortices mixed rapidly, merging into a single large cluster in
only a few seconds, much like a large cyclone forming from the turbulent atmosphere.
"However, the most exciting thing was the remarkable agreement between
theory and experiment -- the theory predicted the shape of the final
giant vortex structures in the superfluid exceptionally well.
"Our results suggest superfluids can be used to learn new things about turbulence, and will be crucial for the development of precision sensors
based on superfluids." This work answers some of the key outstanding
questions from previous work by the team on vortex clusters, which was published in 2019 in Science.
========================================================================== Story Source: Materials provided by University_of_Queensland. Note:
Content may be edited for style and length.
========================================================================== Journal Reference:
1. Matthew T. Reeves, Kwan Goddard-Lee, Guillaume Gauthier, Oliver R.
Stockdale, Hayder Salman, Timothy Edmonds, Xiaoquan Yu, Ashton S.
Bradley, Mark Baker, Halina Rubinsztein-Dunlop, Matthew J. Davis,
Tyler W. Neely. Turbulent Relaxation to Equilibrium in a
Two-Dimensional Quantum Vortex Gas. Physical Review X, 2022; 12
(1) DOI: 10.1103/ PhysRevX.12.011031 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2022/02/220217102044.htm
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