Kolmogorov and Kelvin wave cascades in a generalized model for quantum turbulence

Müller, Nicolás P.; Krstulovic, Giorgio

doi:10.1103/physrevb.102.134513

Cited by 15 publications

(16 citation statements)

References 59 publications

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“…First, we see that the turbulent case displays a clear k −5/3 range, in agreement with the energy spectra obtained from the full GP and NS fields. Note that, in the case of GP fields, we show the incompressible kinetic energy spectrum, which contains 86% of the total energy of the system—the other components being the compressible, internal and quantum energy 20 , 22 . Secondly, the K41 scaling disappears once polarisation is artificially suppressed from the tangle, leading to a trivial k −1 scaling range for the disordered state (see “Methods” for a brief derivation).…”

Section: Introductionmentioning

confidence: 81%

“…Details on the chosen parameters can be found in Ref. 22 . The use of a standard or a generalised GP model does not affect the statistics of velocity circulation 13 .…”

Section: Methodsmentioning

confidence: 99%

“…The generalised GP equation ( 9 ) is solved in a three-dimensional periodic cube by direct numerical simulations using the Fourier pseudospectral code FROST, with an explicit fourth-order Runge–Kutta method for the time integration 22 . The quantum turbulent regime is studied in a freely decaying Arnold–Beltrami–Childress (ABC) flow 13 , 21 with 2048 3 collocation points.…”

Section: Methodsmentioning

confidence: 99%

“…Indeed, at such scales, a Kolmogorov turbulent cascade is observed, provided that a large-scale separation exists between ℓ and the largest scale of the system. In particular, the scaling law predicted by Kolmogorov's celebrated K41 theory 17 for the kinetic energy spectrum has been observed in superfluid helium experiments 18,19 and in numerical simulations of quantum turbulence [20][21][22] .…”

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confidence: 89%

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Vortex clustering, polarisation and circulation intermittency in classical and quantum turbulence

2021

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The understanding of turbulent flows is one of the biggest current challenges in physics, as no first-principles theory exists to explain their observed spatio-temporal intermittency. Turbulent flows may be regarded as an intricate collection of mutually-interacting vortices. This picture becomes accurate in quantum turbulence, which is built on tangles of discrete vortex filaments. Here, we study the statistics of velocity circulation in quantum and classical turbulence. We show that, in quantum flows, Kolmogorov turbulence emerges from the correlation of vortex orientations, while deviations—associated with intermittency—originate from their non-trivial spatial arrangement. We then link the spatial distribution of vortices in quantum turbulence to the coarse-grained energy dissipation in classical turbulence, enabling the application of existent models of classical turbulence intermittency to the quantum case. Our results provide a connection between the intermittency of quantum and classical turbulence and initiate a promising path to a better understanding of the latter.

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Section: Introductionmentioning

confidence: 81%

“…Details on the chosen parameters can be found in Ref. 22 . The use of a standard or a generalised GP model does not affect the statistics of velocity circulation 13 .…”

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 89%

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Vortex clustering, polarisation and circulation intermittency in classical and quantum turbulence

2021

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“…The study of vortices in superfluid 4 He presents some difficulties given that there is not a simple microscopic description of it. However, it is possible to study some of its phenomenology assuming a non-local interaction between the bosons constituting the superfluid [26][27][28][29]. In this framework, a moving obstacle is allowed to emit some density excitations known as rotons [29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Critical velocity for vortex nucleation and roton emission in a generalized model for superfluids

Müller,

Krstulovic

2021

Preprint

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Feynman rules for forced wave turbulence

Rosenhaus

Smolkin

2023

J. High Energ. Phys.

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It has long been known that weakly nonlinear field theories can have a late-time stationary state that is not the thermal state, but a wave turbulent state with a far-from-equilibrium cascade of energy. We go beyond the existence of the wave turbulent state, studying fluctuations about the wave turbulent state. Specifically, we take a classical field theory with an arbitrary quartic interaction and add dissipation and Gaussian-random forcing. Employing the path integral relation between stochastic classical field theories and quantum field theories, we give a prescription, in terms of Feynman diagrams, for computing correlation functions in this system. We explicitly compute the two-point and four-point functions of the field to next-to-leading order in the coupling. Through an appropriate choice of forcing and dissipation, these correspond to correlation functions in the wave turbulent state. In particular, we derive the kinetic equation to next-to-leading order.

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Kolmogorov and Kelvin wave cascades in a generalized model for quantum turbulence

Cited by 15 publications

References 59 publications

Vortex clustering, polarisation and circulation intermittency in classical and quantum turbulence

Vortex clustering, polarisation and circulation intermittency in classical and quantum turbulence

Critical velocity for vortex nucleation and roton emission in a generalized model for superfluids

Feynman rules for forced wave turbulence

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