Anisotropic energy transfers in quasi-static magnetohydrodynamic turbulence

Reddy, K. Sandeep; Kumar, Raghwendra; Verma, Mahendra K.

doi:10.1063/1.4899202

Cited by 53 publications

(58 citation statements)

References 36 publications

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“…In Fig. 13(d,e,f) we exhibit the J (k, θ) that exhibits the above properties for N = 0, 18, 130 respectively [56] . The ring spectra demonstrates that the flow is strongly anisotropic for large N with strong concentration of energy near k ≈ 0 plane.…”

Section: 32mentioning

confidence: 76%

“…Thus, for k > k f , where k f is the forcing wavenumber, F (k) = 0. In this regime, the flux Π(k) will decrease with k since J (k) is active at all scales [57,58,72,74]. This result is contrary to the constant energy flux observed in fluid turbulence in which ν is effective only at large k's (also see Sec.…”

Section: Qs Mhd Equations In the Fourier Spacementioning

confidence: 84%

“…The ratio of the angular distribution of the dissipation rates is given by [57] Thus, ν (k, θ) = J (k, θ) at…”

Section: 32mentioning

confidence: 99%

“…In Fig. 16 we plot the Joule dissipation spectrum [56] J (k) = 2B 2 0 cos 2 θE(k, θ)dθ (100) and the viscous dissipation…”

Section: 32mentioning

confidence: 99%

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Anisotropy in Quasi-Static Magnetohydrodynamic Turbulence

Verma¹

2017

Rep. Prog. Phys.

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In this review we summarise the current status of the quasi-static magnetohydrodynamic turbulence. The energy spectrum is steeper than Kolmogorov's k spectrum due to the decrease of the kinetic energy flux with wavenumber k as a result of Joule dissipation. The spectral index decreases with the increase of interaction parameter. The flow is quasi two-dimensional with strong [Formula: see text] at small k and weak [Formula: see text] at large k, where [Formula: see text] and [Formula: see text] are the perpendicular and parallel components of velocity relative to the external magnetic field. For small k, the energy flux of [Formula: see text] is negative, but for large k, the energy flux of [Formula: see text] is positive. Pressure mediates the energy transfer from [Formula: see text] to [Formula: see text].

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Section: 32mentioning

confidence: 76%

Section: Qs Mhd Equations In the Fourier Spacementioning

confidence: 84%

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Anisotropy in Quasi-Static Magnetohydrodynamic Turbulence

Verma¹

2017

Rep. Prog. Phys.

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“…Note that u ⊥ = u xx + u yŷ and ω z (k) = [ik × u(k)] z . For the cross section at z = π, Figure 4(b,d) illustrates the plots Π (k) in stronglyrotating turbulence is due to the viscous effects, as in Equation (14), and due to energy transfer from u ⊥ to u z , analogous to that in quasi-static MHD 59,79 ; this is in contrast to constant Π starts to decrease at small k itself because the enstrophy dissipation wavenumber, k d , is quite small (see Table III). We compute the enstrophy dissipation wavenumber k d using Equation (15).…”

Section: Energy and Enstrophy Fluxes And Spectramentioning

confidence: 99%

Statistical features of rapidly rotating decaying turbulence: Enstrophy and energy spectra and coherent structures

et al. 2018

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In this paper we investigate the properties of rapidly rotating decaying turbulence using numerical simulations and phenomenological modelling. We find that as the turbulent flow evolves in time, the Rossby number decreases to ∼ 10 −3 , and the flow becomes quasi-two-dimensional with strong coherent columnar structures arising due to the inverse cascade of energy. We establish that a major fraction of energy is confined in Fourier modes (±1, 0, 0) and (0, ±1, 0) that correspond to the largest columnar structure in the flow. For wavenumbers (k) greater than the enstrophy dissipation wavenumber (k d ), our phenomenological arguments and numerical study show that the enstrophy flux and spectrum of a horizontal cross-section perpendicular to the axis of rotation are given by ω exp(−C(k/k d ) 2 ) and C 2/3 ω k −1 exp(−C(k/k d ) 2 ) respectively; for this 2D flow, ω is the enstrophy dissipation rate, and C is a constant. Using these results, we propose a new form for the energy spectrum of rapidly rotating decaying turbulence: E(k) = C 2/3 ω k −3 exp(−C(k/k d ) 2 ). This model of the energy spectrum is based on wavenumber-dependent enstrophy flux, and it deviates significantly from power law energy spectrum reported earlier.

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