Perfect f luid? I like the sound of that
Physicists measure some rare diffusion.
Physicists in the US say they have been able to measure sound diffusion in a “perfect fluid” for the first time.
That’s not just technically impressive – it could, they suggest, be used as a model for more complicated perfect flows to estimate the viscosity of the plasma in the early Universe and even the quantum friction within neutron stars.
“It’s quite difficult to listen to a neutron star,” says Martin Zwierlein from Massachusetts Institute of Technology (MIT), “but now you could mimic it in a lab using atoms, shake that atomic soup and listen to it, and know how a neutron star would sound.”
For physicists, “perfect flow” refers to a fluid that flows with the smallest amount of friction, or viscosity, allowed by the laws of quantum mechanics. It is rare in nature, but is thought to occur in the cores of neutron stars and in the early Universe.
In a paper in the journal
Science, Zwierlein and MIT colleagues describe how they were able to create such a “perfect fluid” in the lab and listen to how sound waves travel through it.
The recording is a product of a glissando of sound waves that the team sent through a carefully controlled gas of elementary particles known as fermions. The pitches that can be heard are the particular frequencies at which the gas resonates like a plucked string.
The researchers analysed thousands of sound waves travelling through this gas, to measure its sound diffusion – how quickly sound dissipates in the gas – which is related directly to a material’s viscosity.
Surprisingly, they say, they found that the fluid’s sound diffusion was so low as to be described by a “quantum” amount of friction, given by a constant of nature known as Planck’s constant and the mass of the individual fermions in the fluid.
This fundamental value confirmed that the strongly interacting fermion gas behaves as a perfect fluid, and is universal in nature.