Kinetic Alfvén Waves From Magnetotail to the Ionosphere in Global Hybrid Simulation Associated With Fast Flows

Cheng, Lei; Lin, Y.; Perez, J. D.; Wang, Xueyi

doi:10.1029/2019ja027062

Cited by 36 publications

(60 citation statements)

References 71 publications

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“…However, in the case of kinetic Alfvén waves, the Walen relation for scales much larger than the electron inertial length is (L. Cheng et al, 2020)  …”

Section: Turbulent Heating Estimatementioning

confidence: 99%

Kelvin–Helmholtz‐Related Turbulent Heating at Saturn's Magnetopause Boundary

Delamere

Damiano

et al. 2021

JGR Space Physics

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One of the grand challenge problems of the giant planet magnetospheres is the issue of nonadiabatic plasma heating. Simple turbulent heating models consider the energy cascade rate from one scale to another where the energy density is based on perpendicular magnetic fluctuations of counterpropagating Alfvén waves. Analytical expressions from turbulence theory for the heating rate density have yielded promising results for the observed ion heating at Jupiter and Saturn. Here, we compare ion heating using hybrid simulations of the Kelvin–Helmholtz instability and analytical estimates in an effort to validate turbulence theory and further understand the nature of the ion heating. Heating rate densities ∼10−15 W/m3 are produced in our three‐dimensional Kelvin–Helmholtz simulations during the nonlinear growth phase and compare favorably with analytical estimates. Results targeting Saturn will be discussed in the broader context of radial plasma transport in the rapidly rotating magnetospheres.

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“…However, in the case of kinetic Alfvén waves, the Walen relation for scales much larger than the electron inertial length is (L. Cheng et al, 2020)  …”

Section: Turbulent Heating Estimatementioning

confidence: 99%

Kelvin–Helmholtz‐Related Turbulent Heating at Saturn's Magnetopause Boundary

Delamere

Damiano

et al. 2021

JGR Space Physics

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“…KAWs as a natural mode of Alfven waves in hot ion plasma (Stasiewicz et al, 2000) are suggested to be generated by several different mechanisms, e.g., mode conversion (Hasegawa and Chen, 1975;Hasegawa, 1976;Lin et al, 2012;Johnson and Cheng, 1997), phase mixing (Guo et al, 2015) and magnetic reconnection (Chaston et al, 2005(Chaston et al, , 2009Liang et al, 2016;Wang et al, 2019b;Cheng et al, 2020). These waves are believed to be responsible for energy transfer from the magnetotail to 10 -1 10 0 10 1 10 2…”

Section: Discussionmentioning

confidence: 99%

Thermal electron anisotropy driven by kinetic Alfven waves in the Earth's magnetotail

Lukin

Artemyev

Panov

et al. 2020

Preprint

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Abstract. Thermal and subthermal electron populations in the Earth's magnetotail are usually characterized by pronounced field-aligned anisotropy that contributes to generation of strong electric currents within the magnetotail current sheet. Formation of this anisotropy requires electron field-aligned acceleration, and thus likely involves field-aligned electric fields. Such fields can be carried by various electromagnetic waves generated by fast plasma flows interacting with ambient magnetotail plasma. In this paper we consider one of the most intense observed wave emissions, kinetic Alfven waves, that often accompany fast plasma flows in the magnetotail. Using two tail seasons (2017, 2018) of MMS observations we have collected statistics of 80 fast plasma flows (or bursty bulk flows) events with distinctive enhancement of intensity of broadband electromagnetic waves (kinetic Alfven waves). We show correlation the intensity of electric fields of kinetic Alfven waves and characteristics of electron anisotropy distributions: the parallel electron anisotropy increases with magnitude of the wave parallel electric field. Also the energy range of this electron anisotropic population is well within the expected acceleration range for assumed kinetic Alfven waves. Our results indicate an important role of KAWs in production of thermal field-aligned electron population typically observed in the Earth's magnetotail.

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“…The solar wind ion temperature is T 0 = 10 eV. This case has previously been studied by Lin, Wang, et al (2014); ; L. Cheng, Lin, et al (2020) for various properties of fast flows in the magnetotail using ANGIE3D. Figure 1 shows the global view of magnetic field strength B at simulation time t = 00:58:27, approximately 1 h after the impact of the solar wind on the magnetosphere, obtained from the global hybrid simulation, together with some typical magnetic field lines (orange solid line).…”

Section: -D Global Hybrid Modelmentioning

confidence: 96%

“…(2014) and L. Cheng, Lin, et al. (2020). A typical time step interval for advancing particles is

normalΔ t = 0.05 {normalΩ}_{0}^{- 1}

, within which a subcycling of 10 steps is applied to the magnetic field update.…”

Section: Simulation Modelmentioning

confidence: 99%

Magnetotail‐Inner Magnetosphere Transport Associated With Fast Flows Based on Combined Global‐Hybrid and CIMI Simulation

et al. 2021

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Using the combined Auburn global hybrid simulation code in 3-D (ANGIE3D) and the Comprehensive Inner Magnetosphere-Ionosphere (CIMI) model, we investigate the self-consistent connection of fast flow injections from the tail plasma sheet and the inner magnetosphere under a southward IMF. In the dynamic run, the hybrid results provide the CIMI model with 3-D magnetic field and the electric potential at the high latitude ionosphere boundary as well as the full ion phase space distribution function at the CIMI outer boundary at the equator. The simulation shows that magnetotail reconnection, which has a dawn-dusk size of ∼1-5 R E , recurs with a period of several minutes, resulting in recurring localized fast flow injections. Strong ion temperature anisotropy and non-Maxwellian distributions are present in the fast flows, and the braking of fast flows due to the dipole-like field results in further perpendicular heating in the injection sources. Multiple fast flow injections lead to multiple peaks in the particle fluxes in the inner magnetosphere as well as layers of upward and downward fieldaligned currents at the ionosphere, and low energy particles penetrate deeper radially than the high energy particles. The combined ANGIE3D-CIMI model can be used to calculate the global kinetic physics that contains both Region-1 and Region-2 field-aligned currents. LIN ET AL.

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Kinetic Alfvén Waves From Magnetotail to the Ionosphere in Global Hybrid Simulation Associated With Fast Flows

Cited by 36 publications

References 71 publications

Kelvin–Helmholtz‐Related Turbulent Heating at Saturn's Magnetopause Boundary

Kelvin–Helmholtz‐Related Turbulent Heating at Saturn's Magnetopause Boundary

Thermal electron anisotropy driven by kinetic Alfven waves in the Earth's magnetotail

Magnetotail‐Inner Magnetosphere Transport Associated With Fast Flows Based on Combined Global‐Hybrid and CIMI Simulation

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