Constraints on ion versus electron heating by plasma turbulence at low beta

Schekochihin, A. A.; Kawazura, Yohei; Barnes, Michael

doi:10.1017/s0022377819000345

Cited by 44 publications

(56 citation statements)

References 124 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…vary slowly in time compared with the ion-cyclotron frequency, that there is a strong background magnetic field, and that the correlation length l of a perturbation in the field-parallel direction is much larger than its field-perpendicular correlation length l ⊥ (Schekochihin et al 2009). The resulting system (gyrokinetics) is still quite complex, and significant further simplification is possible using an expansion in β e ∼ β i 1 (Zocco & Schekochihin 2011;Schekochihin et al 2019). In this case, the ion-thermal speed is small compared with the Alfvén speed, implying there is minimal coupling between perpendicular (Alfvénic) motions and ion-compressive (kinetic) degrees of freedom, even for ion-Larmor-scale fluctuations (Schekochihin et al 2019).…”

Section: Theoretical Frameworkmentioning

confidence: 99%

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

et al. 2021

View full text Add to dashboard Cite

The zeroth law of turbulence states that, for fixed energy input into large-scale motions, the statistical steady state of a turbulent system is independent of microphysical dissipation properties. This behaviour, which is fundamental to nearly all fluid-like systems from industrial processes to galaxies, occurs because nonlinear processes generate smaller and smaller scales in the flow, until the dissipation – no matter how small – can thermalise the energy input. Using direct numerical simulations and theoretical arguments, we show that in strongly magnetised plasma turbulence such as that recently observed by the Parker Solar Probe spacecraft, the zeroth law is routinely violated. Namely, when such turbulence is ‘imbalanced’ – when the large-scale energy input is dominated by Alfvénic perturbations propagating in one direction (the most common situation in space plasmas) – nonlinear conservation laws imply the existence of a ‘barrier’ at scales near the ion gyroradius. This causes energy to build up over time at large scales. The resulting magnetic-energy spectra bear a strong resemblance to those observed in situ, exhibiting a sharp, steep kinetic transition range above and around the ion-Larmor scale, with flattening at yet smaller scales. The effect thus offers a possible solution to the decade-long puzzle of the position and variability of ion-kinetic spectral breaks in plasma turbulence. The existence of the ‘barrier’ also suggests that, how a plasma is forced at large scales (the imbalance) may have a crucial influence on thermodynamic properties such as the ion-to-electron heating ratio.

show abstract

Section: Theoretical Frameworkmentioning

confidence: 99%

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

et al. 2021

View full text Add to dashboard Cite

show abstract

“…The difficulty in observing Landau damping and the concurrent radial heating profile is that it preferentially produces higher parallel temperatures, in conflict with the ion temperature anisotropy T ⊥ /T > 1 observed in the corona and the inner heliosphere for r < 0.5 au. We point the reader to various review articles containing descriptions of solar wind turbulence properties (Chen 2016), heating mechanisms proposed by the community (Cranmer et al 2015), as well as the historical development of the field through theory and observations (Schekochihin 2019).…”

Section: Introductionmentioning

confidence: 99%

The Enhancement of Proton Stochastic Heating in the Near-Sun Solar Wind

Martinović

Klein

Kasper

et al. 2020

ApJS

View full text Add to dashboard Cite

Stochastic heating is a non-linear heating mechanism driven by the violation of magnetic moment invariance due to large-amplitude turbulent fluctuations producing diffusion of ions towards higher kinetic energies in the direction perpendicular to the magnetic field. It is frequently invoked as a mechanism responsible for the heating of ions in the solar wind. Here, we quantify for the first time the proton stochastic heating rate Q ⊥ at radial distances from the Sun as close as 0.16 au, using measurements from the first two Parker Solar Probe encounters. Our results for both the amplitude and radial trend of the heating rate, Q ⊥ ∝ r −2.5 , agree with previous results based on the Helios data set at heliocentric distances from 0.3 to 0.9 au. Also in agreement with previous results, Q ⊥ is significantly larger in the fast solar wind than in the slow solar wind. We identify the tendency in fast solar wind for cuts of the core proton velocity distribution transverse to the magnetic field to exhibit a flat-top shape. The observed distribution agrees with previous theoretical predictions for fast solar wind where stochastic heating is the dominant heating mechanism.

show abstract

“…Numata & Loureiro 2015;Shay et al 2018). Therefore, if reconnecting eddies are a common occurrence -the conditions for which are worked out in this paper -then one might expect turbulence to be efficient at generating nonthermal populations and different electron-to-ion temperature ratios, which are indeed observed or expected in different space and astrophysical plasmas (see, e.g., Schekochihin et al 2019, and references therein). Moreover, the very observability of reconnecting turbulence depends, obviously, on whether truly reconnecting eddies are the norm or an exception.…”

Section: Resultsmentioning

confidence: 76%

Nonlinear Reconnection in Magnetized Turbulence

Loureiro

Boldyrev

2020

ApJ

View full text Add to dashboard Cite

Recent analytical works on strong magnetized plasma turbulence have hypothesized the existence of a range of scales where the tearing instability may govern the energy cascade. In this paper, we estimate the conditions under which such tearing may give rise to full nonlinear magnetic reconnection in the turbulent eddies, thereby enabling significant energy conversion and dissipation. When those conditions are met, a new turbulence regime is accessed where reconnection-driven energy dissipation becomes common, rather than the rare feature that it must be when they are not.

show abstract

Constraints on ion versus electron heating by plasma turbulence at low beta

Cited by 44 publications

References 124 publications

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

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

The Enhancement of Proton Stochastic Heating in the Near-Sun Solar Wind

Nonlinear Reconnection in Magnetized Turbulence

Contact Info

Product

Resources

About