Vortical control of forced two-dimensional turbulence

Fontane, Jérôme; Dritschel, David G.; Scott, R. K.

doi:10.1063/1.4774336

Cited by 15 publications

(9 citation statements)

References 33 publications

(59 reference statements)

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“…In the regime with forward enstrophy transfer, the energy spectrum is typically steeper than k −3 , both in numerical simulations [32] and in experiments [33]. Moreover, Scott [34], Fontane et al [35] report some deviations from the theoretical predictions of Kraichnan [22]. Pandit et al [36] describe properties of 2D flows in the presence of complex forces.…”

Section: Introductionmentioning

confidence: 99%

Energy and enstrophy spectra and fluxes for the inertial-dissipation range of two-dimensional turbulence

et al. 2019

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In this paper, using Pao's conjecture [Y.-H. Pao, Phys. Fluids 8, 1063(1965], we derive expressions for the spectra and fluxes of kinetic energy and enstrophy for two-dimensional (2D) forced turbulence that extend beyond the inertial range. In these expressions, the fluxes and the spectra contain additional factors of the exponential form. To validate these model predictions, we perform numerical simulations of 2D turbulence with external force applied at k = k f in the intermediate range. The numerical results match with the model predictions, except for the energy and enstrophy fluxes for k < k f , where the fluxes exhibit significant fluctuations. We show that these fluctuations arise due to the unsteady nature of the flow at small wavenumbers. For the k < k f , the shellto-shell energy transfers computed using numerical data show forward energy transfers among the neighbouring shells, but backward energy transfers for other shells.

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Section: Introductionmentioning

confidence: 99%

Energy and enstrophy spectra and fluxes for the inertial-dissipation range of two-dimensional turbulence

et al. 2019

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“…In this case strong, nearly-circular coherent vortices can again be unambiguously distinguished from the weak filamentary background flow 6,7,10,[21][22][23][24] . by Kraichnan 9 , and this range extends to larger scales as the minimum allowed distance to vortices increases, as is evident from examining the middle and lower sets of black curves in figure 3b: these spectra correspond, from top to bottom, to increasing minimum distances to vortices.…”

Section: Dmentioning

confidence: 85%

“…by Kraichnan 9 , and this range extends to larger scales as the minimum allowed distance to vortices increases, as is evident from examining the middle and lower sets of black curves in figure 3b: these spectra correspond, from top to bottom, to increasing minimum distances to vortices. Similarly, Fontane et al 6 found E(k) ∼ k −2 for the entire vorticity field, but…”

Section: Dmentioning

confidence: 99%

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Vortex scaling ranges in two-dimensional turbulence

2017

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1We survey the role of coherent vortices in two-dimensional turbulence, including formation mechanisms, implications for classical similarity and inertial range theories, and characteristics of the vortex populations. We review early work on the spatial and temporal scaling properties of vortices in freely evolving turbulence, and more recent developments, including a spatiotemporal scaling theory for vortices in the forced inverse energy cascade. We emphasize that Kraichnan-Batchelor similarity theories and vortex scaling theories are best viewed as complementary, and together provide a more complete description of two-dimensional turbulence. In particular, similarity theory has a continued role in describing the weak filamentary sea between the vortices. Moreover, we locate both classical inertial and vortex scaling ranges within the broader framework of scaling in far-from-equilibrium systems, which generically exhibit multiple fixed point solutions with distinct scaling behaviour. We describe how stationary transport in a range of scales comoving with the dilatation of flow features, as measured by the growth in vortex area, constrains the vortex number density in both freely evolving and forced two-dimensional turbulence.The new theories for coherent vortices reveal previously hidden nontrivial scaling, point to new dynamical understanding, and provide a novel exciting window into two-dimensional turbulence. CONTENTS

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“…The fate of random initial vorticity distributions on a sphere complex vorticity distributions and in doubly periodic or spherical domains this clean scaling law has been questioned (Fontane, Dritschel & Scott 2013). When the viscosity is reduced little by little (i.e.…”

Section: Overviewmentioning

confidence: 99%

The fate of random initial vorticity distributions for two-dimensional Euler equations on a sphere

Newton

2015

J. Fluid Mech.

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The paper by Dritschel et al. (J. Fluid Mech., vol. 783, 2015, pp. 1-22) describes the long-time behaviour of inviscid two-dimensional fluid dynamics on the surface of a sphere. At issue is whether the flow settles down to an equilibrium or whether, for generic (random) initial conditions, the long-time solution is periodic, quasi-periodic or chaotic. While it might be surprising that this issue is not settled in the literature, it is important to keep in mind that the Euler equations form a dissipationless Hamiltonian system, hence the set of equations only redistributes the initial vorticity, generating smaller and smaller scales, while keeping kinetic energy, angular impulse and an infinite family of vorticity moments (Casimirs) intact. While special solutions that never settle down to an equilibrium state can be constructed using point vortices, vortex patches and other distributions, the fate of random initial conditions is a trickier problem. Previous statistical theories indicate that the long-time state should be a stationary large-scale distribution of vorticity. By carrying out careful numerical simulations using two different methods, the authors make a compelling case that the generic long-time state resembles a large-scale oscillating quadrupolar vorticity field, surrounded by persistent small-scale vortices. While numerical simulations can never conclusively settle this issue, the results might help guide future theories that seek to prove the existence of such an interesting dynamical long-time state.

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Vortical control of forced two-dimensional turbulence

Cited by 15 publications

References 33 publications

Energy and enstrophy spectra and fluxes for the inertial-dissipation range of two-dimensional turbulence

Energy and enstrophy spectra and fluxes for the inertial-dissipation range of two-dimensional turbulence

Vortex scaling ranges in two-dimensional turbulence

The fate of random initial vorticity distributions for two-dimensional Euler equations on a sphere

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