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1. Cross-scale energy transfer from fluid-scale Alfv\'en waves to kinetic-scale ion acoustic waves in the Earth's magnetopause boundary layer

Author

An, Xin, Artemyev, Anton, Angelopoulos, Vassilis, Liu, Terry Z., Vasko, Ivan, and Malaspina, David

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics
Abstract

In space plasmas, large-amplitude Alfv\'en waves can drive compressive perturbations, accelerate ion beams, and lead to plasma heating and the excitation of ion acoustic waves at kinetic scales. This energy channelling from fluid to kinetic scales represents a complementary path to the classical turbulent cascade. Here, we present observational and computational evidence to validate this hypothesis by simultaneously resolving the fluid-scale Alfv\'en waves, kinetic-scale ion acoustic waves, and their imprints on ion velocity distributions in the Earth's magnetopause boundary layer. We show that two coexisting compressive modes, driven by the magnetic pressure gradients of Alfv\'en waves, not only accelerate the ion tail population to the Alfv\'en velocity, but also heat the ion core population near the ion acoustic velocity and generate Debye-scale ion acoustic waves. Thus, Alfv\'en-acoustic energy channeling emerges as a viable mechanism for plasma heating near plasma boundaries where large-amplitude Alfv\'en waves are present.

Published
2024

3. Small-amplitude Compressible Magnetohydrodynamic Turbulence Modulated by Collisionless Damping in Earth's Magnetosheath: Observation Matches Theory

Author

Zhao, Siqi, Yan, Huirong, Liu, Terry Z., Yuen, Ka Ho, and Shi, Mijie

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies, Physics - Plasma Physics, Physics - Space Physics
Abstract

Plasma turbulence is a ubiquitous dynamical process that transfers energy across many spatial and temporal scales and affects energetic particle transport. Recent advances in the understanding of compressible magnetohydrodynamic (MHD) turbulence demonstrate the important role of damping in shaping energy distributions on small scales, yet its observational evidence is still lacking. This study provides the first observational evidence of substantial collisionless damping (CD) modulation on small-amplitude compressible MHD turbulence cascade in Earth's magnetosheath using four Cluster spacecraft. Based on an improved compressible MHD decomposition algorithm, turbulence is decomposed into three eigenmodes: incompressible Alfv\'en modes, and compressible slow and fast (magnetosonic) modes. Our observations demonstrate that CD enhances the anisotropy of compressible MHD modes because CD has a strong dependence on wave propagation angle. The wavenumber distributions of slow modes are mainly stretched perpendicular to the background magnetic field ($\mathbf{B_0}$) and weakly modulated by CD. In contrast, fast modes are subjected to a more significant CD modulation. Fast modes exhibit a weak, scale-independent anisotropy above the CD truncation scale. Below the CD truncation scale, the anisotropy of fast modes enhances as wavenumbers increase. As a result, fast mode fractions in the total energy of compressible modes decrease with the increase of perpendicular wavenumber (to $\mathbf{B_0}$) or wave propagation angle. Our findings reveal how the turbulence cascade is shaped by CD and its consequences to anisotropies in the space environment., Comment: Main text: 5 pages, 6 figures. Accepted by ApJ on Dec. 5, 2023. Published on Feb. 08, 2024

Published
2023
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4. Identification of the weak-to-strong transition in Alfv\'enic turbulence from space plasma

Author

Zhao, Siqi, Yan, Huirong, Liu, Terry Z., Yuen, Ka Ho, and Wang, Huizi

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Astrophysics of Galaxies, Physics - Plasma Physics, Physics - Space Physics
Abstract

Plasma turbulence is a ubiquitous dynamical process that transfers energy across many spatial and temporal scales in astrophysical and space plasma systems. Although the theory of anisotropic magnetohydrodynamic (MHD) turbulence has successfully described phenomena in nature, its core prediction of an Alfvenic transition from weak to strong MHD turbulence when energy cascades from large to small scales has not been observationally confirmed. Here we report the first observational evidence for the Alfvenic weak-to-strong transition in MHD turbulence in the terrestrial magnetosheath using the four Cluster spacecraft. The observed transition indicates the universal existence of strong turbulence regardless of the initial level of MHD fluctuations. Moreover, the observations demonstrate that the nonlinear interactions of MHD turbulence play a crucial role in the energy cascade, widening the directions of the energy cascade and broadening the fluctuating frequencies. Our work takes a critical step toward understanding the complete picture of turbulence cascade, connecting the weak and strong MHD turbulence systems. It will have broad implications in star formation, energetic particle transport, turbulent dynamo, and solar corona or solar wind heating., Comment: submitted; 24 pages; 4 figures

Published
2023
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5. Multi-spacecraft Analysis of the Properties of Magnetohydrodynamic Fluctuations in Sub-Alfv\'enic Solar Wind Turbulence at 1 AU

Author

Zhao, S. Q., Yan, Huirong, Liu, Terry Z., Liu, Mingzhe, and Wang, Huizi

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies, Physics - Space Physics
Abstract

We present three-dimensional magnetic power spectra in wavevector space to investigate anisotropy and scalings of sub-Alfv\'enic solar wind turbulence at magnetohydrodynamic (MHD) scale using the Magnetospheric Multiscale spacecraft. The magnetic power distributions are organized in a new coordinate determined by wavevectors (k) and background magnetic field ($b_0$) in Fourier space. This study utilizes two approaches to determine wavevectors: singular value decomposition method and timing analysis. The combination of the two methods allows an examination of magnetic field properties in terms of mode compositions without any spatiotemporal hypothesis. Observations show that fluctuations ($\delta B_{\perp1}$) in the direction perpendicular to k and $b_0$ prominently cascade perpendicular to $b_0$, and such anisotropy increases with wavenumber. The reduced power spectra of $\delta B_{\perp1}$ follow Goldreich-Sridhar scalings: $P(k_\perp)\sim k_\perp^{-5/3}$ and $P(k_{||}) \sim k_{||}^{-2}$. In contrast, fluctuations within $kb_0$ plane show isotropic behaviors: perpendicular power distributions are approximately the same as parallel distributions. The reduced power spectra of fluctuations within $kb_0$ plane follow the scalings: $P(k_\perp)\sim k_\perp^{-3/2}$ and $P(k_{||})\sim k_{||}^{-3/2}$. Comparing frequency-wavevector spectra with theoretical dispersion relations of MHD modes, we find that $\delta B_{\perp1}$ are probably associated with Alfven modes. Moreover, for the Alfv\'enic component, the ratio of cascading time to the wave period is found to be a factor of a few, consistent with critical balance in the strong turbulence regime. The magnetic field fluctuations within $kb_0$ plane more likely originate from fast modes based on isotropic behaviors., Comment: 24 pages; 11 Figures; ApJ accepted

Published
2022
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6. Observations of an Electron-cold Ion Component Reconnection at the Edge of an Ion-scale Antiparallel Reconnection at the Dayside Magnetopause

Author

Zhao, S. Q., Zhang, H., Liu, Terry Z., Yan, Huirong, Xiao, C. J., Liu, Mingzhe, Zong, Q. -G., Wang, Xiaogang, Shi, Mijie, Teng, Shangchun, Wang, Huizi, Rankin, R., Pollock, C., and Le, G.

Subjects
Physics - Space Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics
Abstract

Solar wind parameters play a dominant role in reconnection rate, which controls the solar wind-magnetosphere coupling efficiency at Earth's magnetopause. Besides, low-energy ions from the ionosphere, frequently detected on the magnetospheric side of the magnetopause, also affect magnetic reconnection. However, the specific role of low-energy ions in reconnection is still an open question under active discussion. In the present work, we report in situ observations of a multiscale, multi-type magnetopause reconnection in the presence of low-energy ions using NASA's Magnetospheric Multiscale data on 11 September 2015. This study divides ions into cold and hot populations. The observations can be interpreted as a secondary reconnection dominated by electrons and cold ions located at the edge of an ion-scale reconnection. This analysis demonstrates a dominant role of cold ions in the secondary reconnection without hot ions' response. Cold ions and electrons are accelerated and heated by the secondary process. The case study provides observational evidence for the simultaneous operation of antiparallel and component reconnection. Our results imply that the pre-accelerated and heated cold ions and electrons in the secondary reconnection may participate in the primary ion-scale reconnection affecting the solar wind-magnetopause coupling and the complicated magnetic field topology affect the reconnection rate.

Published
2021
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7. Analysis of Magnetohydrodynamic Perturbations in Radial-field Solar Wind from Parker Solar Probe Observations

Author

Zhao, S. Q., Yan, Huirong, Liu, Terry Z., Liu, Mingzhe, and Shi, Mijie

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics
Abstract

We report analysis of sub-Alfv\'enic magnetohydrodynamic (MHD) perturbations in the low-\b{eta} radial-field solar wind using the Parker Solar Probe spacecraft data from 31 October to 12 November 2018. We calculate wave vectors using the singular value decomposition method and separate the MHD perturbations into three types of linear eigenmodes (Alfv\'en, fast, and slow modes) to explore the properties of the sub-Alfv\'enic perturbations and the role of compressible perturbations in solar wind heating. The MHD perturbations there show a high degree of Alfv\'enicity in the radial-field solar wind, with the energy fraction of Alfv\'en modes dominating (~45%-83%) over those of fast modes (~16%-43%) and slow modes (~1%-19%). We present a detailed analysis of a representative event on 10 November 2018. Observations show that fast modes dominate magnetic compressibility, whereas slow modes dominate density compressibility. The energy damping rate of compressible modes is comparable to the heating rate, suggesting the collisionless damping of compressible modes could be significant for solar wind heating. These results are valuable for further studies of the imbalanced turbulence near the Sun and possible heating effects of compressible modes at MHD scales in low-\b{eta} plasma., Comment: 17 pages, 8 figures, accepted for publication in ApJ

Published
2021
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8. Magnetospheric Multiscale (MMS) observations of foreshock transients at their very early stage

Author

Liu, Terry Z., An, Xin, Zhang, Hui, and Turner, Drew

Subjects
Physics - Space Physics
Abstract

Foreshock transients are ion kinetic structures in the ion foreshock. Due to their dynamic pressure perturbations, they can disturb the bow shock and magnetosphere-ionosphere system. They can also accelerate particles contributing to shock acceleration. However, it is still unclear how exactly they form. Recent particle-in-cell simulations point out the important role of electric field and Hall current in the formation process. To further examine this, we use data from the Magnetospheric Multiscale (MMS) mission to apply case studies on two small (1000-2000 km) foreshock transient events that just started to form. In event 1 where MMS were in a tetrahedral formation, we show that the current density configuration, which determined the magnetic field profile, was mainly driven by Hall currents generated by demagnetized foreshock ions. The resulting time variation of the magnetic field induced electric field that drove cold plasma moving outward with magnetic field lines. In event 2 where MMS were in a string-of-pearls formation, we analyze the evolution of field and plasma parameters. We show that the magnetic flux and mass flux were transported outward from the core resulting in the steepening of the boundary. The steepened boundary, which trapped more foreshock ions and caused stronger demagnetization of foreshock ions, nonlinearly further enhanced the Hall current. Based on our observations, we propose a physical formation process that the positive feedback of foreshock ions on the varying magnetic field caused by the foreshock ion Hall current enables an instability and the growth of the structure., Comment: Accepted by ApJ

Published
2020
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9. Formation of foreshock transients and associated secondary shocks

Author

An, Xin, Liu, Terry Z., Bortnik, Jacob, Osmane, Adnane, and Angelopoulos, Vassilis

Subjects
Physics - Space Physics, Physics - Plasma Physics
Abstract

Upstream of shocks, the foreshock is filled with hot ions. When these ions are concentrated and thermalized around a discontinuity, a diamagnetic cavity bounded by compressional boundaries, referred to as a foreshock transient, forms. Sometimes, the upstream compressional boundary can further steepen into a secondary shock, which has been observed to accelerate particles and contribute to the primary shock acceleration. However, secondary shock formation conditions and processes are not fully understood. Using particle-in-cell simulations, we reveal how secondary shocks are formed. From 1D simulations, we show that electric fields play a critical role in shaping the shock's magnetic field structure, as well as in coupling the energy of hot ions to that of the shock. We demonstrate that larger thermal speed and concentration ratio of hot ions favors the formation of a secondary shock. From a more realistic 2D simulation, we examine how a discontinuity interacts with foreshock ions leading to the formation of a foreshock transient and a secondary shock. Our results imply that secondary shocks are more likely to occur at primary shocks with higher Mach number. With the secondary shock's previously proven ability to accelerate particles in cooperation with a planetary bow shock, it is even more appealing to consider them in particle acceleration of high Mach number astrophysical shocks., Comment: Accepted for publication in the Astrophysical Journal

Published
2020
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10. Electron acceleration by magnetosheath jet-driven bow waves

Author

Liu, Terry Z., Hietala, Heli, Angelopoulos, Vassilis, Vainio, Rami, and Omelchenko, Yuri

Subjects
Physics - Space Physics
Abstract

Magnetosheath jets are localized fast flows with enhanced dynamic pressure. When they supermagnetosonically compress the ambient magnetosheath plasma, a bow wave or shock can form ahead of them. Such a bow wave was recently observed to accelerate ions and possibly electrons. The ion acceleration process was previously analyzed, but the electron acceleration process remains largely unexplored. Here we use multi-point observations by Time History of Events and Macroscale during Substorms from three events to determine whether and how magnetosheath jet-driven bow waves can accelerate electrons. We show that when suprathermal electrons in the ambient magnetosheath convect towards a bow wave, some electrons are shock-drift accelerated and reflected towards the ambient magnetosheath and others continue moving downstream of the bow wave resulting in bi-directional motion. Our study indicates that magnetosheath jet-driven bow waves can result in additional energization of suprathermal electrons in the magnetosheath. It implies that magnetosheath jets can increase the efficiency of electron acceleration at planetary bow shocks or other similar astrophysical environments., Comment: Under review by JGR space physics

Published
2020
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11. Statistical study of magnetosheath jet-driven bow waves

Author

Liu, Terry Z., Hietala, Heli, Angelopoulos, Vassilis, Omelchenko, Yuri, Vainio, Rami, and Plaschke, Ferdinand

Subjects
Physics - Space Physics
Abstract

When a magnetosheath jet (localized dynamic pressure enhancements) compresses ambient magnetosheath at a (relative) speed faster than the local magnetosonic speed, a bow wave or shock can form ahead of the jet. Such bow waves or shocks were recently observed to accelerate particles, thus contributing to magnetosheath heating and particle acceleration in the extended environment of Earth bow shock. To further understand the characteristics of jet-driven bow waves, we perform a statistical study to examine which solar wind conditions favor their formation and whether it is common for them to accelerate particles. We identified 364 out of 2859 (13%) magnetosheath jets to have a bow wave or shock ahead of them with Mach number typically larger than 1.1. We show that large solar wind plasma beta, weak interplanetary magnetic field (IMF) strength, large solar wind Alfven Mach number, and strong solar wind dynamic pressure present favorable conditions for their formation. We also show that magnetosheath jets with bow waves or shocks are more frequently associated with higher maximum ion and electron energies than those without them, confirming that it is common for these structures to accelerate particles. In particular, magnetosheath jets with bow waves have electron energy flux enhanced on average by a factor of 2 compared to both those without bow waves and the ambient magnetosheath. Our study implies that magnetosheath jets can contribute to shock acceleration of particles especially for high Mach number shocks. Therefore, shock models should be generalized to include magnetosheath jets and concomitant particle acceleration., Comment: Under review by JGR space physics

Published
2020
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13. Statistical Analysis of Whistler Precursors Upstream of Foreshock Transient Shocks: MMS Observations

Author

Wang, Mengmeng, primary, Liu, Terry Z., additional, Zhang, Hui, additional, Liu, Kaijun, additional, Shi, Quanqi, additional, Guo, Ruilong, additional, Tian, Anmin, additional, Sun, Weijie, additional, Shen, Xiao‐Chen, additional, Wu, Siyuan, additional, Degeling, Alexander W., additional, Wang, Yan, additional, Bai, Shi‐Chen, additional, Yao, Zhonghua, additional, Li, Wenya, additional, Zhang, Shuai, additional, Pitkänen, Timo, additional, Yao, Shutao, additional, Liu, Ji, additional, Cheng, Kun, additional, Ma, Xiao, additional, and Liu, Yuqi, additional

Published
2024
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14. Multi Satellite Observation of a Foreshock Bubble Causing an Extreme Magnetopause Expansion

Author

Grimmich, Niklas, primary, Prencipe, Fabio, additional, Turner, Drew L., additional, Liu, Terry Z., additional, Plaschke, Ferdinand, additional, Archer, Martin O., additional, Nakamura, Rumi, additional, Sibeck, David G., additional, Mieth, Johannes Z. D., additional, Auster, Hans‐Ulrich, additional, Constantinescu, O. Dragos, additional, Fischer, David, additional, and Magnes, Werner, additional

Published
2024
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16. Relativistic electrons generated at Earth’s quasi-parallel bow shock

Author

Liu, Terry Z, Angelopoulos, Vassilis, and Lu, San

Subjects
Engineering, Astronomical Sciences, Aerospace Engineering, Physical Sciences
Abstract

Plasma shocks are the primary means of accelerating electrons in planetary and astrophysical settings throughout the universe. Which category of shocks, quasi-perpendicular or quasi-parallel, accelerates electrons more efficiently is debated. Although quasi-perpendicular shocks are thought to be more efficient electron accelerators, relativistic electron energies recently observed at quasi-parallel shocks exceed theoretical expectations. Using in situ observations at Earth's bow shock, we show that such relativistic electrons are generated by the interaction between the quasi-parallel shock and a related nonlinear structure, a foreshock transient, through two betatron accelerations. Our observations show that foreshock transients, overlooked previously, can increase electron acceleration efficiency at a quasi-parallel shock by an order of magnitude. Thus, quasi-parallel shocks could be more important in generating relativistic electrons, such as cosmic ray electrons, than previously thought.

Published
2019

18. Fermi acceleration of electrons inside foreshock transient cores

Author

Liu, Terry Z., Lu, San, Angelopoulos, Vassilis, Hietala, Heli, and Wilson III, Lynn B.

Subjects
Physics - Space Physics
Abstract

Foreshock transients upstream of Earth's bow shock have been recently observed to accelerate electrons to many times their thermal energy. How such acceleration occurs is unknown, however. Using THEMIS case studies, we examine a subset of acceleration events (31 of 247 events) in foreshock transients with cores that exhibit gradual electron energy increases accompanied by low background magnetic field strength and large-amplitude magnetic fluctuations. Using the evolution of electron distributions and the energy increase rates at multiple spacecraft, we suggest that Fermi acceleration between a converging foreshock transient's compressional boundary and the bow shock is responsible for the observed electron acceleration. We then show that a one-dimensional test particle simulation of an ideal Fermi acceleration model in fluctuating fields prescribed by the observations can reproduce the observed evolution of electron distributions, energy increase rate, and pitch-angle isotropy, providing further support for our hypothesis. Thus, Fermi acceleration is likely the principal electron acceleration mechanism in at least this subset of foreshock transient cores., Comment: Submitted to JGR

Published
2017
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19. Statistical study of particle acceleration in the core of foreshock transients

Author

Liu, Terry Z., Angelopoulos, Vassilis, Hietala, Heli, and Wilson III, Lynn B.

Subjects
Physics - Space Physics
Abstract

Several types of foreshock transients upstream of Earth's bow shock possessing a tenuous, hot core have been observed and simulated. Because of the low dynamic pressure in their cores, these phenomena can significantly disturb the bow shock and the magnetosphere-ionosphere system. Recent observations have also demonstrated that foreshock transients can accelerate particles which, when transported earthward, can affect space weather. Understanding the potential of foreshock transients to accelerate particles can help us understand shock acceleration at Earth and at other planetary and astrophysical systems. To further investigate foreshock transients' potential for acceleration we conduct a statistical study of ion and electron energization in the core of foreshock transients. We find that electron energies typically increase there, evidently due to an internal acceleration process, whereas, as expected, ion energies most often decrease to support transient formation and expansion. Nevertheless, ion energy enhancements can be seen in some events suggesting an internal ion acceleration process as well. Formation conditions of foreshock transients are related to weak solar wind magnetic field strength and fast solar wind speed. Ion and electron energization are also positively correlated with solar wind speed., Comment: Submitted to JGR

Published
2017
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20. 2.5‐D Local Hybrid Simulations of Discontinuity‐Driven Compressional Boundaries Under Various Magnetic Field Geometries.

Author

Vu, Andrew, Liu, Terry Z., Angelopoulos, Vassilis, and Zhang, Hui

Subjects
HYBRID computer simulation, MAGNETIC fields, LEAD, MAGNETO
Abstract

In the ion foreshock, there are many foreshock transients driven by back streaming foreshock ions. When the foreshock ions interact with tangential discontinuities (TDs), hot flow anomalies form if the foreshock ion‐driven current decreases field strength at TDs, but the opposite situation has been paid little attention. Using 2.5‐D local hybrid simulations, we show that a compressional boundary with enhanced field strength and density can form. We examine how the foreshock ions interact with TDs under various magnetic field geometries to drive currents that lead to compressional boundaries. The current driven by the foreshock ions should peak on its initial side of a TD so that the enhanced field strength at the TD in turn increases this current by keeping more foreshock ions on their initial side. Which side the current peaks can be determined by whether the foreshock ions initially cross the TD and/or how their velocity is projected into the local perpendicular direction. Additionally, the foreshock ion‐driven currents from two sides could compete, and whether a compressional boundary forms is determined by the net current profile. Because such compressive structures in the foreshock can drive magneto sheath jets and cause many geoeffects, it is necessary to fully understand their formation. Key Points: We conduct 2.5D local hybrid simulations to study discontinuity‐driven compressional boundaries under various magnetic field geometriesForeshock ion‐driven current direction and whether the current peaks on its initial side play a critical role in formationForeshock ions from two sides could compete, and the net current determines whether a compressional boundary forms [ABSTRACT FROM AUTHOR]

Published
2024
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23. Cross-scale physics and the acceleration of particles in collisionless plasmas throughout the Heliosphere and beyond: I. Collisionless shocks

Author

Turner, Drew L., primary, III, Lynn B. Wilson,, additional, Goodrich, Katy, additional, Cohen, Ian J., additional, Liu, Terry Z., additional, Schwartz, Steven J., additional, Caprioli, Damiano, additional, Haggerty, Colby, additional, Gingell, Imogen, additional, Hill, Matt, additional, Provornikova, Elena, additional, Mostafavi, Parisa, additional, Kollmann, Peter, additional, Brandt, Pontus, additional, McNutt, Ralph, additional, and Lavraud, Benoit, additional

Published
2023
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30. Compressible Magnetohydrodynamic Turbulence Modulated by Collisionless Damping in Earth's Magnetosheath: Observation Matches Theory

Author

Zhao, Siqi, Yan, Huirong, Liu, Terry Z., Yuen, Ka Ho, and Shi, Mijie

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Astrophysics of Galaxies (astro-ph.GA), FOS: Physical sciences, Astrophysics - Astrophysics of Galaxies, Physics - Plasma Physics, Solar and Stellar Astrophysics (astro-ph.SR), Space Physics (physics.space-ph), Astrophysics - Earth and Planetary Astrophysics
Abstract

In this letter, we provide the first observational evidence of substantial collisionless damping (CD) modulation in the magnetohydrodynamic (MHD) turbulence cascade in Earth's magnetosheath using four Cluster spacecraft. Plasma turbulence is primarily shaped by the forcing on large scales and damping on small scales. Based on an improved compressible MHD decomposition algorithm, our observations demonstrate that CD enhances the anisotropy of compressible MHD modes due to their strong pitch angle dependence. The wavenumber distributions of slow modes are more stretched perpendicular to the background magnetic field ($\mathbf{B_0}$) under CD modulation compared to Alfv\'en modes. In contrast, fast modes are subject to a more significant CD modulation. Fast modes exhibit a scale-independent, slight anisotropy above the CD truncation scales, and their anisotropy increases as the wavenumbers fall below the CD truncation scales. As a result, CD affects the relative energy fractions in total compressible modes. Our findings take a significant step forward in comprehending the functions of CD in truncating the compressible MHD turbulence cascade and the consequential energy anisotropy in the wavevector space., Comment: Main text: 5 pages, 4 figures. Submitted to PRL on May 11, 2023

Published
2023
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36. Multispacecraft Analysis of the Properties of Magnetohydrodynamic Fluctuations in Sub-Alfvénic Solar Wind Turbulence at 1 au

Author

Zhao, Siqi, Yan, Huirong, Liu, Terry Z., Liu, Mingzhe, and Wang, Huizi

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Astrophysics of Galaxies (astro-ph.GA), Physics::Space Physics, FOS: Physical sciences, ddc:520, Astrophysics - Astrophysics of Galaxies, Solar and Stellar Astrophysics (astro-ph.SR), Space Physics (physics.space-ph), Astrophysics - Earth and Planetary Astrophysics
Abstract

The astrophysical journal 937(2), 102 (2022). doi:10.3847/1538-4357/ac822e, We present three-dimensional magnetic power spectra in wavevector space to investigate anisotropy and scalings of sub-Alfv\'enic solar wind turbulence at magnetohydrodynamic (MHD) scale using the Magnetospheric Multiscale spacecraft. The magnetic power distributions are organized in a new coordinate determined by wavevectors (k) and background magnetic field ($b_0$) in Fourier space. This study utilizes two approaches to determine wavevectors: singular value decomposition method and timing analysis. The combination of both methods allows an examination of magnetic field properties in terms of mode compositions without spatiotemporal hypothesis. Observations show that fluctuations ($\delta B_{\perp1}$) in the direction perpendicular to k and $b_0$ prominently cascade perpendicular to $b_0$, and such anisotropy increases with wavenumber. The reduced power spectra of $\delta B_{\perp1}$ follow Goldreich-Sridhar scalings: $P(k_\perp)\sim k_\perp^{-5/3}$ and $P(k_{||}) \sim k_{||}^{-2}$. In contrast, fluctuations within $kb_0$ plane show isotropic behaviors: perpendicular power distributions are approximately the same as parallel distributions. The reduced power spectra of fluctuations within $kb_0$ plane follow the scalings: $P(k_\perp)\sim k_\perp^{-3/2}$ and $P(k_{||})\sim k_{||}^{-3/2}$. Comparing frequency-wavevector spectra with theoretical dispersion relations of MHD modes, we find that $\delta B_{\perp1}$ are probably associated with Alfven modes. For Alfvenic components, the ratio of cascading rate to the wave frequency is found to be around a factor of one, fully consistent with critical balance in the strong turbulence regime. The magnetic field fluctuations within $kb_0$ plane more likely originate from fast modes based on isotropic behaviors. The anisotropy and scalings of different magnetic field components are consistent with predictions of the current compressible MHD theory., Published by Univ., Chicago, Ill. [u.a.]

Published
2022
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40. Observations of an Electron‐Cold Ion Component Reconnection at the Edge of an Ion‐Scale Antiparallel Reconnection at the Dayside Magnetopause

Author

Zhao, S. Q., primary, Zhang, H., additional, Liu, Terry Z., additional, Yan, Huirong, additional, Xiao, C. J., additional, Liu, Mingzhe, additional, Zong, Q.‐G., additional, Wang, Xiaogang, additional, Shi, Mijie, additional, Teng, Shangchun, additional, Wang, Huizi, additional, Rankin, R., additional, Pollock, C., additional, and Le, G., additional

Published
2021
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43. Analysis of Magnetohydrodynamic Perturbations in the Radial-field Solar Wind from Parker Solar Probe Observations

Author

Zhao, Siqi, Yan, Huirong, Liu, Terry Z., Liu, Mingzhe, and Shi, Mijie

Subjects
Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Physics::Plasma Physics, Physics::Space Physics, FOS: Physical sciences, Astrophysics::Solar and Stellar Astrophysics, ddc:520, Solar and Stellar Astrophysics (astro-ph.SR), Space Physics (physics.space-ph), Physics - Plasma Physics
Abstract

The astrophysical journal 923(2), 253 (2021). doi:10.3847/1538-4357/ac2ffe, We report analysis of sub-Alfv��nic magnetohydrodynamic (MHD) perturbations in the low-�� radial-field solar wind employing the Parker Solar Probe spacecraft data from 2018 October 31 to November 12. We calculate wavevectors using the singular value decomposition method and separate MHD perturbations into three eigenmodes (Alfv��n, fast, and slow modes) to explore the properties of sub-Alfv��nic perturbations and the role of compressible perturbations in solar wind heating. The MHD perturbations show a high degree of Alfv��nicity in the radial-field solar wind, with the energy fraction of Alfv��n modes dominating (���45%���83%) over those of fast modes (���16%���43%) and slow modes (���1%���19%). We present a detailed analysis of a representative event on 2018 November 10. Observations show that fast modes dominate magnetic compressibility, whereas slow modes dominate density compressibility. The energy damping rate of compressible modes is comparable to the heating rate, suggesting the collisionless damping of compressible modes could be significant for solar wind heating. These results are valuable for further studies of the imbalanced turbulence near the Sun and possible heating effects of compressible modes at MHD scales in low-�� plasma., Published by Univ., Chicago, Ill. [u.a.]

Published
2021

44. Monte Carlo Simulations of Electron Acceleration at Bow Waves Driven by Fast Jets in the Earth’s Magnetosheath.

Author

Vuorinen, Laura, Vainio, Rami, Hietala, Heli, and Liu, Terry Z.

Subjects
MONTE Carlo method, PARTICLE acceleration, ELECTRONS, MAGNETIC traps, PLASMA flow, SOLAR wind
Abstract

The shocked solar wind flows around the Earth’s magnetosphere in the magnetosheath downstream of the Earth’s bow shock. Within this region, faster flows of plasma, called magnetosheath jets, are frequently observed. These jets have been shown to sometimes exhibit supermagnetosonic speeds relative to the magnetosheath flow and to develop bow waves or shocks of their own. Such jet-driven bow waves have been observed to accelerate ions and electrons. We model electron acceleration by magnetosheath jet-driven bow waves using test-particle Monte Carlo simulations. Our simulations suggest that the energy increase of electrons with energies of a few hundred eV to 10 keV can be explained by a collapsing magnetic trap forming between the bow wave and the magnetopause with shock drift acceleration at the moving bow wave. Our simulations allow us to estimate the efficiency of acceleration as a function of different jet and magnetosheath parameters. Electron acceleration by jet-driven bow waves can increase the total acceleration in the parent shock environment, most likely also at shocks other than the Earth’s bow shock. [ABSTRACT FROM AUTHOR]

Published
2022
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