2014
DOI: 10.1073/pnas.1312539111
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Quantum turbulence in superfluids with wall-clamped normal component

Abstract: In Fermi superfluids, such as superfluid 3 He, the viscous normal component can be considered to be stationary with respect to the container. The normal component interacts with the superfluid component via mutual friction, which damps the motion of quantized vortex lines and eventually couples the superfluid component to the container. With decreasing temperature and mutual friction, the internal dynamics of the superfluid component becomes more important compared with the damping and coupling effects from th… Show more

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Cited by 19 publications
(13 citation statements)
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“…Temperature thus plays an analogous role to that of the Reynolds number in classical turbulence (27). This type of quantum turbulence is discussed in the article by Eltsov et al (59).…”
Section: Types and Regimes Of Quantum Turbulencementioning
confidence: 94%
“…Temperature thus plays an analogous role to that of the Reynolds number in classical turbulence (27). This type of quantum turbulence is discussed in the article by Eltsov et al (59).…”
Section: Types and Regimes Of Quantum Turbulencementioning
confidence: 94%
“…Related effects are seen in rotating superfluid 3 He-B where at very low temperatures the lack of normal fluid disconnects the superfluid from the rotating container [17][18][19] . This scenario is shown schematically in panel g of Fig.…”
mentioning
confidence: 98%
“…Following lead (ii), a mechanism explaining the influence of the hot-wire signal to quantum intervortex distance in the outerflow is as follows: in a mechanically driven quantum turbulence, the mutual friction between the normal and superfluid components couples their turbulent fluctuations: u n (r, t) ≈ u s (r, t) at all scales larger than the intervortex scale δ. The resulting turbulent energy spectra of the mechanically driven quantum turbulence for the scales much greater than δ are close to those of the classical hydrodynamic turbulence [2,3,[26][27][28][29][30]. However, u n (r, t) and u s (r, t) decouple at scales of the order of δ.…”
Section: B Interpretationmentioning
confidence: 61%