On the violation of the zeroth law of turbulence in space plasmas

Meyrand, Romain; Squire, Jonathan; Schekochihin, A. A.; Dorland, W.

doi:10.1017/s0022377821000489

Cited by 49 publications

(60 citation statements)

References 73 publications

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“…Fully kinetic simulations in the presence of such a barrier [82] show the generation of quasi-parallel cyclotron modes, similar to those observed in the solar wind. This barrier to imbalanced energy flux [82,88] provides a novel method for generating cyclotron waves that can dissipate imbalanced turbulence that is consistent with a variety of observations [58,59,78,[89][90][91][92][93]. Further work is required to understand the origin of cyclotron waves and their connection to turbulence.…”

supporting

confidence: 52%

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The In Situ Signature of Cyclotron Resonant Heating

Bowen¹,

Squire²,

Bale³

et al. 2021

Preprint

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The dissipation of magnetized turbulence is an important paradigm for describing heating and energy transfer in astrophysical environments such as the solar corona and wind; however, the specific collisionless processes behind dissipation and heating remain relatively unconstrained by measurements. Remote sensing observations have suggested the presence of strong temperature anisotropy in the solar corona consistent with cyclotron resonant heating. In the solar wind, in situ magnetic field measurements reveal the presence of cyclotron waves, while measured ion velocity distribution functions have hinted at the active presence of cyclotron resonance. Here, we present Parker Solar Probe observations that connect the presence of ion-cyclotron waves directly to signatures of resonant damping in observed proton-velocity distributions. We show that the observed cyclotron wave population coincides with both flattening in the phase space distribution predicted by resonant quasilinear diffusion and steepening in the turbulent spectra at the ion-cyclotron resonant scale. In measured velocity distribution functions where cyclotron resonant flattening is weaker, the distributions are nearly uniformly subject to ion-cyclotron wave damping rather than emission, indicating that the distributions can damp the observed wave population. These results are consistent with active cyclotron heating in the solar wind.

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supporting

confidence: 52%

“…However, recent work suggests that imbalance, i.e. the dominance of the outward Alfvén mode, may prevent energy from cascading to kinetic scales [88]. Fully kinetic simulations in the presence of such a barrier [82] show the generation of quasi-parallel cyclotron modes, similar to those observed in the solar wind.…”

mentioning

confidence: 95%

The In Situ Signature of Cyclotron Resonant Heating

Bowen¹,

Squire²,

Bale³

et al. 2021

Preprint

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“…The dispersive kinetic waves allow nonlinear interaction between the copropagating wave packets, which can lead to a steepened transition range at ion scales, but the required imbalance for α t < − 3.5 is much stronger than the observation (Voitenko & Keyser 2016). On the other hand, there is a proposed "helicity barrier" from the finite-Larmorradius MHD in β p = 1 plasma near the ion scales preventing the energy cascading to the smaller scales (Meyrand et al 2021). Only a small portion of energy would leak through the barrier and produce a steep transition range.…”

Section: Conclusion and Discussionmentioning

confidence: 96%

“…Sometimes a sharp transition range is observed with α t ∼ 4 (Sahraoui et al 2010;Bowen et al 2020a). This transition range may be caused by imbalanced turbulence (Voitenko & Keyser 2016;Meyrand et al 2021), energy dissipation of kinetic waves (Howes et al 2008), ion-scale coherent structures (Lion et al 2016), or a reconnection dominated range (Mallet et al 2017). At smaller scales, a flatter sub-ion kinetic range forms with the spectral index α k ∼ 7/3, which can be explained as the MHD Alfvénic turbulence developing into a type of kinetic wave turbulence, e.g., kinetic Alfvén waves (KAWs; Schekochihin et al 2009) or whistler waves (Cho & Lazarian 2004).…”

Section: Introductionmentioning

confidence: 99%

Anisotropy of Solar Wind Turbulence in the Inner Heliosphere at Kinetic Scales: PSP Observations

Duan

Bowen

et al. 2021

ApJL

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The anisotropy of solar wind turbulence is a critical issue in understanding the physics of energy transfer between scales and energy conversion between fields and particles in the heliosphere. Using the measurement of Parker Solar Probe (PSP), we present an observation of the anisotropy at kinetic scales in the slow, Alfvénic, solar wind in the inner heliosphere. The magnetic compressibility behaves as expected for kinetic Alfvénic turbulence below the ion scale. A steepened transition range is found between the inertial and kinetic ranges in all directions with respect to the local background magnetic field direction. The anisotropy of k ⊥ ? k P is found evident in both transition and kinetic ranges, with the power anisotropy P ⊥ /P P > 10 in the kinetic range leading over that in the transition range and being stronger than that at 1 au. The spectral index varies from α tP = −5.7 ± 1.0 to α t⊥ = −3.7 ± 0.3 in the transition range and α kP = −3.12 ± 0.22 to α k⊥ = −2.57 ± 0.09 in the kinetic range. The corresponding wavevector anisotropy has the scaling of k k 0.71 0.17 ~^ in the transition range, and changes to k k 0.38 0.09 ~^ in the kinetic range, consistent with the kinetic Alfvénic turbulence at sub-ion scales.

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“…In summary, the Saffman-type-invariant approach appears to be an extremely useful tool for describing the decay of turbulence subject to the conservation of signindefinite invariants. There are many different types of fluid turbulence to which this approach may be usefully applied -a number of them are reviewed in [5], and there are likely to be others, especially in a large variety of plasma systems increasingly of interest in the context of various types of space or astrophysical turbulence (see, e.g., [52][53][54]). In the physical systems where frozenin magnetic fields are dominant actors in the dynamics, magnetic reconnection is likely to be the key physical process whereby the decay occurs.…”

Section: Non-helical Magnetic Fieldmentioning

confidence: 99%

Reconnection-controlled decay of magnetohydrodynamic turbulence and the role of invariants

Hosking,

Schekochihin

2020

Preprint

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On the violation of the zeroth law of turbulence in space plasmas

Cited by 49 publications

References 73 publications

The In Situ Signature of Cyclotron Resonant Heating

The In Situ Signature of Cyclotron Resonant Heating

Anisotropy of Solar Wind Turbulence in the Inner Heliosphere at Kinetic Scales: PSP Observations

Reconnection-controlled decay of magnetohydrodynamic turbulence and the role of invariants

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