Anisotropic Electron Heating in Turbulence-driven Magnetic Reconnection in the Near-Sun Solar Wind

Franci, Luca; Papini, Emanuele; Micera, Alfredo; Lapenta, Giovanni; Hellinger, Petr; Sarto, D. Del; Burgess, David; Landi, Simone

doi:10.3847/1538-4357/ac7da6

Cited by 16 publications

(6 citation statements)

References 121 publications

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“…The contribution by E || (Figure 6b) has a slight decreasing trend over time, where the median value is above 50% at the early time and below 50% later. The dominant role of E || energization is consistent with recent observations in magnetosheath turbulence where the pdf of the work done by E || to electrons is found (Xu et al, 2023), and kinetic simulations of turbulence where T e|| enhancements are found to be significant around the reconnection onset (Franci et al, 2022). For the decomposition of j e⊥ • E ⊥ , at the later time, the relative importance is consistent with the laminar reconnection studies (e.g., Dahlin et al, 2014Dahlin et al, , 2015Dahlin et al, , 2016Li et al, 2015Li et al, , 2017: the Fermi term (Figure 6c) dominates the positive contribution, and the Betatron term (Figure 6d) is negative.…”

Section: Electron Energizationsupporting

confidence: 88%

Electron Heating Associated With Magnetic Reconnection in Foreshock Waves: Particle‐In‐Cell Simulation Analysis

Wang,

Yang

2023

JGR Space Physics

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Magnetic reconnection occurs in turbulent plasmas like shock transition regions, while its role in energy dissipation therein is not yet clear. We perform a 2D particle‐in‐cell simulation of foreshock waves and study electron heating associated with reconnection. The probability distribution of Te exhibits a shift to higher values near reconnection X‐lines compared to elsewhere. By examining the Te evolution using the superposed epoch analysis, we find that Te is higher in reconnection than in non‐reconnecting current sheets, and Te increases over the ion cyclotron time scale. The heating rate of Te is 10%–40% miVA2, where VA is the average ion Alfvén speed in reconnection regions, which demonstrates the importance of reconnection in heating electrons. We further investigate the bulk electron energization mechanisms by decomposing je · E under guiding center approximations. Around the reconnection onset, E|| dominates the total energization partly contributed by electron holes, and the perpendicular energization is dominated by the magnetization term associated with the gyro‐motion in inhomogeneous fields. The Fermi mechanism contributes negative energization at early time mainly due to Hall effects, and later the outflow in the reconnection plane contributes more dominant positive values. After a couple of ion cyclotron periods from reconnection onset, the Fermi mechanism dominates the energization. A critical factor for initiating reconnection is to drive current sheets to the de‐scale thickness. The reconnection structures can be complicated due to flows originated from the ion‐scale waves, and interactions between multiple reconnection sites. Visualizing such complicated features in simulations may assist future analysis of observation data.

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Section: Electron Energizationsupporting

confidence: 88%

Electron Heating Associated With Magnetic Reconnection in Foreshock Waves: Particle‐In‐Cell Simulation Analysis

Wang,

Yang

2023

JGR Space Physics

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“…We identify three potential mechanisms that could possibly provide external thermal energy sources or sinks to the electrons in the form of nonzero Ξ: turbulent heating, instabilities, and collisions. The turbulent cascade transfers energy from large scales to kinetic scales, where kinetic processes dissipate the energy in the form of heat (Tu & Marsch 1995;Breech et al 2009;Schekochihin et al 2009;Bruno & Carbone 2013;Goldstein et al 2015;Livadiotis 2019;Franci et al 2022). This form of turbulent dissipation leads to an irreversible deposition of thermal energy.…”

Section: Discussionmentioning

confidence: 99%

Thermal Energy Budget of Electrons in the Inner Heliosphere: Parker Solar Probe Observations

Abraham

Verscharen

Wicks

et al. 2022

ApJ

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We present an observational analysis of the electron thermal energy budget using data from Parker Solar Probe. We use the macroscopic moments, obtained from our fits to the measured electron distribution function, to evaluate the thermal energy budget based on the second moment of the Boltzmann equation. We separate contributions to the overall budget from reversible and irreversible processes. We find that an irreversible thermal energy source must be present in the inner heliosphere over the heliocentric distance range from 0.15 to 0.47 au. The divergence of the heat flux is positive at heliocentric distances below 0.33 au, while beyond 0.33 au, there is a measurable degradation of the heat flux. Expansion effects dominate the thermal energy budget below 0.3 au. Under our steady-state assumption, the free streaming of the electrons is not sufficient to explain the observed thermal energy density budget. We conjecture that the most likely driver for the required heating process is turbulence. Our results are consistent with the known nonadiabatic polytropic index of the electrons, which we measure as 1.18 in the explored range of heliocentric distances.

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“…It is not clear at what spatial scales the pressure-strain effect acts. Electron and ion energisations are expected to work at very different scales (Franci et al 2022), but comparable scales are observed in some full-particle simulations (Yang et al 2022). It is also unclear what the role of the turbulence anisotropy is (most of the present simulations are two-dimensional) and how it compares to other processes such as Hall coupling (Papini et al 2019(Papini et al , 2021.…”

Section: Introductionmentioning

confidence: 68%

Anisotropy of plasma turbulence at ion scales: Hall and pressure–strain effects

Hellinger,

Verdini,

Montagud-Camps

et al. 2024

A&A

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We investigated the properties of plasma turbulence at ion scales in the solar wind context. We concentrated on the behaviour of the Hall physics and the pressure strain interaction and their anisotropy owing to the ambient magnetic field. We studied the results of a three-dimensional hybrid simulation of decaying plasma turbulence using the K\'arm\'an-Howarth-Monin (KHM) equation, which quantifies different turbulent processes. The isotropised KHM analysis shows that kinetic plus magnetic (kinetic+magnetic) energy decays at large scales; this energy cascades from large to small scales via the magneto-hydrodynamic non-linearity that is partly continued via the Hall coupling around the ion scales. The cascading kinetic+magnetic energy is partly dissipated at small scales via resistive dissipation. This standard dissipation is complemented by the pressure-strain interaction, which plays the role of an effective dissipation mechanism and starts to act at relatively large scales. The pressure--strain interaction has two components, compressive and incompressive. Compressive interaction is connected with the velocity dilatation, which mostly reversibly exchanges kinetic+magnetic and internal energies. Incompressive interaction mostly irreversibly converts the kinetic+magnetic energy to internal energy. The compressive effects lead to important oscillations of the turbulence properties, but the compressibility is strongly reduced when averaged over a time period spanning a few periods of the oscillations. The ambient magnetic field induces a strong spectral anisotropy. The turbulent fluctuations exhibit larger scales along the magnetic field compared to the perpendicular directions. The KHM results show the corresponding anisotropy of turbulent processes: their characteristic scales shift to larger scales in the quasi-parallel direction with respect to the ambient magnetic field compared to the quasi-perpendicular direction. This anisotropy is weak at large scales owing to the initial isotropic spectrum, and becomes progressively stronger at small scales.

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Anisotropic Electron Heating in Turbulence-driven Magnetic Reconnection in the Near-Sun Solar Wind

Cited by 16 publications

References 121 publications

Electron Heating Associated With Magnetic Reconnection in Foreshock Waves: Particle‐In‐Cell Simulation Analysis

Electron Heating Associated With Magnetic Reconnection in Foreshock Waves: Particle‐In‐Cell Simulation Analysis

Thermal Energy Budget of Electrons in the Inner Heliosphere: Parker Solar Probe Observations

Anisotropy of plasma turbulence at ion scales: Hall and pressure–strain effects

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