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The effects of finite electron inertia on helicity-barrier-mediated turbulence

Published online by Cambridge University Press:  18 September 2024

T. Adkins*
Affiliation:
Department of Physics, University of Otago, Dunedin 9016, New Zealand
R. Meyrand
Affiliation:
Department of Physics, University of Otago, Dunedin 9016, New Zealand
J. Squire
Affiliation:
Department of Physics, University of Otago, Dunedin 9016, New Zealand
*
Email address for correspondence: toby.adkins1@gmail.com

Abstract

Understanding the partitioning of turbulent energy between ions and electrons in weakly collisional plasmas is crucial for the accurate interpretation of observations and modelling of various astrophysical phenomena. Many such plasmas are ‘imbalanced’, wherein the large-scale energy input is dominated by Alfvénic fluctuations propagating in a single direction. In this paper, we demonstrate that when strongly-magnetised plasma turbulence is imbalanced, nonlinear conservation laws imply the existence of a critical value of the electron plasma beta (the ratio of the thermal to magnetic pressures) that separates two dramatically different types of turbulence in parameter space. For betas below the critical value, the free energy injected on the largest scales is able to undergo a familiar Kolmogorov-type cascade to small scales where it is dissipated, heating electrons. For betas above the critical value, the system forms a ‘helicity barrier’ that prevents the cascade from proceeding past the ion Larmor radius, causing the majority of the injected free energy to be deposited into ion heating. Physically, the helicity barrier results from the inability of the system to adjust to the disparity between the perpendicular-wavenumber scalings of the free energy and generalised helicity below the ion Larmor radius; restoring finite electron inertia can annul, or even reverse, this disparity, giving rise to the aforementioned critical beta. We relate this physics to the ‘dynamic phase alignment’ mechanism (that operates under yet lower beta conditions and in pair plasmas), and characterise various other important features of the helicity barrier, including the nature of the nonlinear wavenumber-space fluxes, dissipation rates, and energy spectra. The existence of such a critical beta has important implications for heating, as it suggests that the dominant recipient of the turbulent energy, ions or electrons, can depend sensitively on the characteristics of the plasma at large scales.

Information

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press
Figure 0

Figure 1. The phase velocity (2.9), normalised to the Alfvén speed, plotted as a function of perpendicular wavenumber $k_{\perp } \rho _{\rm i}$, and for $\tau = Z =1$. The colours indicate the value of $\beta _{\rm e} (m_{\rm e}/m_{\rm i})^{-1}$ for a given line, with the solid black line showing the FLR-MHD case ($d_{\rm e} \rightarrow 0$). The dotted lines are the scalings (2.11). The vertical shaded region indicates wavenumbers $k_{\perp } \rho _{\rm e} > 1$ for which the model ceases to apply. The inset panel shows the case of $\beta _{\rm e} = m_{\rm e}/m_{\rm i}$, with the horizontal dashed line indicating $v_{\text {ph}}/v_{\rm A} = 1$.

Figure 1

Table 1. The parameters used for the isothermal KREHM simulations considered in this paper. All simulations have $\tau = Z = 1$. Values in parentheses indicate the minimum and maximum values for the corresponding column, with the final column (‘Sims’) indicating the number of simulations in a given set. A dash in an entry indicates that the physical simulation being considered does not contain that physical parameter.

Figure 2

Figure 2. One-dimensional perpendicular energy spectra for the ‘high-resolution’ simulations in table 1: CF (blue), HB (red) and RMHD (green). Solid and dashed lines correspond to (a) $E_\perp ^+(k_{\perp })$ and $E_\perp ^-(k_{\perp })$ or (b) $E_\perp ^K(k_{\perp })$ and $E_\perp ^B(k_{\perp })$, respectively. The insets panels show the local scaling exponents $\alpha _{(\dots )} = \text {d} \log E^{(\dots )}_\perp /\text {d} \log k_{\perp }$ for each spectrum. The inertial-range scalings (3.10), (3.15) and (3.16) are shown by black dotted lines (with $-5/3$ scalings replaced with $-3/2$, as discussed following (3.11)). Note that the axis of the (scale-invariant) RMHD simulation has been rescaled for comparison with the other two cases. Both simulations CF (constant flux) and RMHD are expected to saturate via a constant-flux cascade, and show good agreement with the predicted scalings, whereas simulation HB (helicity barrier) exhibits entirely different scalings.

Figure 3

Figure 3. Time evolution of the spectral energy fluxes $\varPi ^\pm (k_{\perp })$ computed directly from the nonlinear terms in (2.7) and (2.8), normalised to the total energy flux $\varepsilon _{W}$. Simulations CF and HB from table 1 are shown in panels (a) and (b), respectively. The colours indicate the value of time corresponding to a given line, whereas the solid black lines correspond to the average value of each flux over the last $20\,\%$ of the simulation time. The horizontal dashed lines indicate the values of the flux (3.5) expected if the system is able to maintain a constant flux; we have included a line corresponding to ${\varepsilon ^{-}}$ in the upper panel of (b) for ease of comparison. It is clear that the total flux reaching small scales in the presence of the helicity barrier is significantly smaller than in the constant flux case (note that, in both cases, the decrease in the flux at small scales is due to the presence of perpendicular hyperdissipation).

Figure 4

Figure 4. The free energy and its dissipation rates as a function of time for simulations CF (blue) and HB (red). The top panel shows the free energy, whereas middle panel shows the parallel and perpendicular dissipation rates, $D_{\parallel }$ and $D_{\perp }$, in dashed and solid lines, respectively. The bottom panel shows the dissipation ratio (3.24). It is clear that $R_{\text {diss}} \ll 1$ for the constant-flux case, while $R_{\text {diss}}$ grows slowly to $\approx 1$ for the helicity-barrier one.

Figure 5

Figure 5. Time evolution of the perpendicular spectra $E_\perp ^\pm (k_{\perp })$ for simulations CF and HB in table 1, shown in panels (a) and (b), respectively. The colours indicate the value of time corresponding to a given line, whereas the dotted black lines indicate approximate scalings of the spectra. The inset panels show the scaling exponents $\alpha ^\pm = \text {d} \log E_\perp ^\pm /\text {d} \log k_{\perp }$ for each spectrum. In the helicity barrier case, the $E_\perp ^+(k_{\perp })$ spectrum clearly forms a spectral break that moves towards large scales in time.

Figure 6

Figure 6. Real-space snapshots of the $\boldsymbol {E} \times \boldsymbol {B}$ flow $\boldsymbol {u}_{\perp }$ (see (2.3)) for the simulations CF-res (left) and HB-res (right). The colours indicate the magnitude of $\boldsymbol {u}_{\perp }$ relative to its (spatial) root-mean-square value, whereas the coordinate directions are as shown. Although the structure of the turbulence in simulation CF-res is typical of a constant-flux cascade (though note the significant small-scale plasmoid activity due to finite $d_{\rm e}$ effects; see Zhou et al.2023b), this is not the case for simulation HB-res: the majority of the energy resides in large-scale structures because it is prevented from cascading to small scales by the helicity barrier. The dramatic difference between these two cases is made even more surprising by the fact that the simulations differ only in their value of the electron inertial length, having $d_{\rm e} = \rho _{\rm i}$ and ${d_{\rm e} = \rho _{\rm i}/2}$, respectively.

Figure 7

Figure 7. Measures of the dissipation associated with the set of eight simulations with $\sigma _{\varepsilon } = 0.8$ from the set labelled ‘beta scan’ in table 1. (a) The dissipation ratio (3.24) plotted as a function of time. The colours indicate the value of $\beta /\beta _{\rm e}^{\text {crit}}$ for each simulation. (b) The two-dimensional spectrum of the dissipation in the $(k_{\perp }, k_z)$ plane, averaged over the last $20\,\%$ of the simulation time, and normalised to the energy injection rate $\varepsilon _{W}$, with amplitude as indicated by the colourbar.

Figure 8

Figure 8. Data from a two-dimensional parameter scan of injection imbalance $\sigma _{\varepsilon }$ versus the (normalised) electron plasma beta $\beta _{\rm e} (m_{\rm e}/m_{\rm i})^{-1}$. Each circle corresponds to a simulation from the set ‘beta scan’ in table 1, with filled/open circles indicating the presence/absence of the helicity barrier. The solid black line corresponds to the value of $\sigma _{\varepsilon }$ below which, for a given $\beta _{\rm e}$, the helicity barrier should not form (cf. (3.23)). The shaded region below the line thus corresponds to saturation via constant flux, whereas above it a helicity barrier forms. The inset plot shows the time-averaged average value of the rate-of-change of the dissipation ratio (3.24) normalised to $\varepsilon _{H}/H$ for each set of simulations, as indicated by the colour, with the horizontal axis rescaled by the critical beta (3.23). The horizontal dotted line therein corresponds to the value (3.25) above which the helicity barrier is determined to have formed.

Figure 9

Figure 9. Data from a two-dimensional parameter scan of injection imbalance $\sigma _{\varepsilon }$ versus the maximum wavenumber $k_{\perp }^\text {max} \rho _{\rm i}$ set by the numerical resolution. Each circle corresponds to a simulation from the set ‘resolution scan’ in table 1, with filled/open circles indicating the presence/absence of the helicity barrier. The solid black line corresponds to the value of $\sigma _{\varepsilon }$ below which, for a given $k_{\perp }^\text {max} \rho _{\rm i}$, the helicity barrier should not form (see (3.26)). As in figure 8, the shaded region below the line thus corresponds to saturation via constant flux, whereas above it a helicity barrier forms. The inset plot shows the time-averaged average value of the rate-of-change of the dissipation ratio (3.24) normalised to $\varepsilon _{H}/H$ for each set of simulations, as indicated by the colour, with the horizontal axis rescaled by $2k_{\perp }^\text {crit} \rho _{\rm i}$. The horizontal dotted line therein corresponds to the value (3.25) above which the helicity barrier is determined to have formed.

Figure 10

Figure 10. The phase angle (3.19) between fluctuations of the electrostatic potential $\phi$ and parallel magnetic vector potential ${A_{\parallel }}$, as a function of perpendicular wavenumber, for the three simulations labelled ‘comparison’ in table 1 (solid lines). Simulations CF and HB both have $\rho _{\rm i} = 0.1 L$ and finite $d_{\rm e}$, whereas simulation ULB has $d_{\rm e} =0.1 L$ but $\rho _{\rm i} \rightarrow 0$. The dashed lines show the theoretical scaling (3.20), whereas the dotted black line shows the expected scaling in the ultra-low-beta regime. We do not expect exact agreement between (3.20) and (3.19) because the former is a result derived using a ratio of fluxes (see § 3.2) whereas for the latter we are plotting a ratio of amplitudes (or, equivalently, energies).