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1. Nonlinear Electron Trapping Through Cyclotron Resonance in the Formation of Chorus Subpackets

Author

Huayue Chen, Xueyi Wang, Lunjin Chen, Xiao‐Jia Zhang, Yoshiharu Omura, Rui Chen, Yi‐Kai Hsieh, Yu Lin, and Zhiyang Xia

Subjects
chorus waves, nonlinear trapping through cyclotron resonance, trapping period, timescale of chorus subpackets, electron dynamics, self‐consistent particle‐in‐cell simulation, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Chorus subpackets are the wave packets with modulated amplitudes in chorus waves, commonly observed in the magnetospheres of Earth and other planets. Nonlinear wave‐particle interactions have been suggested to play an important role in subpacket formation, yet the corresponding electron dynamics remain not fully understood. In this study, we have investigated the electron trapping through cyclotron resonance with subpackets, using a self‐consistent general curvilinear plasma simulation code simulation model in dipole fields. The electron trapping period has been quantified separately through electron dynamic analysis and theoretical derivation. Both methods indicate that the electron trapping period is shorter than the subpacket period/duration. We have further established the relation between electron trapping period and subpacket period through statistical analysis using simulation and observational data. Our study demonstrates that the nonlinear electron trapping through cyclotron resonance is the dominant mechanism responsible for subpacket formation.

Published
2024
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2. Resonant Electron Signatures in the Formation of Chorus Wave Subpackets

Author

Xueyi Wang, Huayue Chen, Yoshiharu Omura, Yi‐Kai Hsieh, Lunjin Chen, Yu Lin, Xiao‐Jia Zhang, and Zhiyang Xia

Subjects
chorus wave subpackets, nonlinear wave‐particle interaction, cyclotron resonance, Landau resonance, Earth's magnetosphere, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract A 2‐D GCPIC simulation in a dipole field system has been conducted to explore the excitation of oblique whistler mode chorus waves driven by energetic electrons with temperature anisotropy. The rising tone chorus waves are initially generated near the magnetic equator, consisting of a series of subpackets, and become oblique during their propagation. It is found that electron holes in the wave phase space, which are formed due to the nonlinear cyclotron resonance, oscillate in size with time during subpacket formation. The associated inhomogeneity factor varies accordingly, giving rise to various frequency chirping in different phases of subpackets. Distinct nongyrotropic electron distributions are detected in both wave gyrophase and stationary gyrophase. Landau resonance is found to coexist with cyclotron resonance. This study provides multidimensional electron distributions involved in subpacket formation, enabling us to comprehensively understand the nonlinear physics in chorus wave evolution.

Published
2024
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4. Evolution of Chorus Subpackets in the Earth's Magnetosphere

Author

Huayue Chen, Xueyi Wang, Lunjin Chen, Yoshiharu Omura, Bruce T. Tsurutani, Yu Lin, and Zhiyang Xia

Subjects
chorus wave subpackets, nonlinear wave‐particle interactions, frequency chirping, upstream source region, chirping rate, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Chorus subpackets/subelements are the wave packets occurring at intervals of ∼10–100 msec and are suggested to play a crucial role in the formation of substructures within pulsating aurora. In this study, we investigate the evolution of subpackets from the upstream to downstream regions. Using Van Allen Probe A measurements, we have found that the frequency of the upstream subpackets increases smoothly, but that of the downstream subpackets remains almost unchanged. Through a simulation in the real‐size magnetosphere, we have reproduced the subpackets with characteristics similar to those in observations, and revealed that the frequency chirping is influenced by both resonant current of electrons and wave amplitude due to nonlinear physics. Although the resonant currents in the upstream and downstream regions are comparable, the wave amplitude increases significantly during evolution, resulting in lower sweep rate in the downstream region. Our findings provide a fresh insight into the evolution of chorus subpackets.

Published
2023
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5. The Repetition Period of MeV Electron Microbursts as Measured by SAMPEX/HILT

Author

Hamdan Kandar, Lauren Blum, Mykhaylo Shumko, Lunjin Chen, and Jih‐Hong Shue

Subjects
microbursts, chorus waves, repetition, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Here we examine properties of MeV electron microbursts to better understand their generation mechanisms. Using 15 years of data from Solar, Anomalous, Magnetospheric Particles Explorer/Heavy Ion Large Telescope, >1 MeV microburst repetition periods (time spacing between bursts) are examined and clear dependencies on Auroral Electrojet (AE), L shell, and magnetic local time (MLT) are discovered. Microburst repetition periods are shortest around 0–6 hr MLT and 4–5 L shell, and grow longer toward the day and afternoon sectors and larger L shells. Shorter repetition periods (10 s) more common during quiet times. The microburst repetition period distributions are compared directly to those of rising tone chorus wave elements and found to be similar in the night, dawn and day MLT sectors, suggesting chorus wave repetition periods are likely directly controlling those of microburst precipitation. However, dusk‐side distributions differ, indicating that the dusk‐side microbursts properties may be controlled by other processes.

Published
2023
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6. Simulation of Downward Frequency Chirping in the Rising Tone Chorus Element

Author

Huayue Chen, Xueyi Wang, Lunjin Chen, Yoshiharu Omura, Quanming Lu, Rui Chen, Zhiyang Xia, and Xinliang Gao

Subjects
frequency chirping of chorus wave, hole and hill structures in the electron phase space, nonlinear wave‐particle interaction, resonant current, Earth’s inner magnetosphere, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract The frequency chirping of chorus waves is commonly observed in the Earth’s inner magnetosphere, but its generation remains an open question. Recently, Liu et al. (2021), https://doi.org/10.1029/2021JA029258 reported two unusual rising‐tone (upward chirping) chorus elements. Although the central frequency of constituent subpackets rises, the frequency of a single subpacket is surprisingly downward chirping. With a gcPIC‐δf simulation in the dipole field, we successfully reproduce this kind of substructure, which contains alternating signs of chirping. Interestingly, both hole and hill structures are formed around the theoretical resonant velocities in the electron phase space, no matter whether the chirping is upward or downward. However, during each chirping interval, only one structure (either a hole or a hill) is associated with wave excitation: the upward chirping is related to the hole, while the hill contributes to the downward chirping. Our study provides a fresh perspective on the theory of frequency chirping in chorus waves.

Published
2023
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7. Latitudinal dependence of ground VLF transmitter wave power in the inner magnetosphere

Author

Zhiyang Xia, Lunjin Chen, Wenyao Gu, Richard B. Horne, Yoshizumi Miyoshi, Yoshiya Kasahara, Atsushi Kumamoto, Fuminori Tsuchiya, Satoko Nakamura, Masahiro Kitahara, and Iku Shinohara

Subjects
VLF transmitter, whistler wave, wave propagation, ray tracing, inner magnetosphere, ERG/Arase, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

In this study, we use approximately 3 years of observations from the Exploration of energization and Radiation in Geospace (ERG/Arase) satellite to statistically study the meridional distribution of wave power from very-low-frequency (VLF) ground transmitters in the inner magnetosphere and analyze the corresponding latitudinal dependence. The results show that the mean intensity of NWC transmitter signals decreases as the transmitter emission propagates from the southern latitude (∼—30°) region to the equator in the inner magnetosphere and then increases as the emission propagates to the northern latitude (∼30°) region again. Similar latitudinal dependence can be found from the Van Allen Probes’ observation with a narrower latitude range (∼−20° to 0°). A ray-tracing simulation of the transmitter emission propagation is performed and reproduces a meridional wave power distribution similar to the observation. Similar latitudinal dependence can also be found for NAA, NLK and NLM transmitters.

Published
2023
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8. Understanding the properties, wave drivers, and impacts of electron microburst precipitation: Current understanding and critical knowledge gaps

Author

Sadie S. Elliott, Aaron Breneman, Christopher Colpitts, Jacob Bortnik, Allison Jaynes, Alexa Halford, Mykhaylo Shumko, Lauren Blum, Lunjin Chen, Ashley Greeley, and Drew Turner

Subjects
microbursts, chorus, radiation belts, precipitation, wave-particle interactions, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Microbursts are impulsive (

Published
2022
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9. Electron Microbursts Induced by Nonducted Chorus Waves

Author

Lunjin Chen, Xiao-Jia Zhang, Anton Artemyev, Liheng Zheng, Zhiyang Xia, Aaron W. Breneman, and Richard B. Horne

Subjects
chorus, microbursts, radiation belts, precipitation, wave-particle interaction, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Microbursts, short-lived but intense electron precipitation observed by low-Earth-orbiting satellites, may contribute significantly to the losses of energetic electrons in the outer radiation belt. Their origin is likely due to whistler mode chorus waves, as evidenced by a strong overlap in spatial correlation of the two. Despite previous efforts on modeling bursty electron precipitation induced by chorus waves, most, if not all, rely on the assumption that chorus waves are ducted along the field line with zero wave normal angle. Such ducting is limited to cases when fine-scale plasma density irregularities are present. In contrast, chorus waves propagate in a nonducted way in plasmas with smoothly varying density, allowing wave normals to gradually refract away from the magnetic field line. In this study, the interaction of ducted and nonducted chorus waves with energetic electrons is investigated using test particle simulation. Substantial differences in electron transport are found between the two different scenarios, and resultant electron precipitation patterns are compared. Such a comparison is valuable for interpreting low Earth-orbiting satellite observations of electron flux variation in response to the interaction with magnetospheric chorus waves.

Published
2021
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10. On the Impacts of Ions of Ionospheric Origin and Their Composition on Magnetospheric EMIC Waves

Author

Justin H. Lee, Lauren W. Blum, and Lunjin Chen

Subjects
EMIC waves, cold plasma, wave-particle interactions, cold ions, energetic particle precipitation, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Large numbers of theory and observation studies have been conducted on electromagnetic ion cyclotron (EMIC) waves occurring in Earth’s magnetosphere. Numerous studies have shown that accurately specifying the ions of ionospheric origin and their composition can greatly improve understanding of magnetospheric EMIC waves, specifically their generation, their properties, and their effects on the magnetospheric plasma populations. With the launch and operations of multiple recent missions carrying plasma instrumentation capable of acquiring direct measurements of multiple ion species, we use this opportunity to review recent magnetospheric EMIC wave efforts utilizing these new assets, with particular focus on the role of ions of ionospheric origin in wave generation, propagation, and interaction with particles. The review of progress leads us to a discussion of the unresolved questions to be investigated using future modeling capabilities or when new missions or instrumentation capabilities are developed.

Published
2021
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11. Understanding the Properties, Wave Drivers, and Impacts of Electron Microburst Precipitation: Current Understanding and Critical Knowledge Gaps

Author

Sadie Elliott, Allison Jaynes, Jacob Bortnik, Aaron Breneman, Christopher Colpitts, Alexa J Halford, Mykhaylo Shumko, Lauren Blum, Lunjin Chen, Ashley Greeley, and Drew Turner

Subjects
Space Sciences (General)
Abstract

Microbursts are impulsive (~100ms) injections of very energetic to relativistic electrons (energies from a few keV to MeV) into Earth’s atmosphere. Microbursts are important because they may represent a major loss process for the outer radiation belt (Ripoll et al., 2020). Understanding and quantifying the underlying causes and consequences plus relative importance of microburst precipitation represent outstanding questions in radiation belt physics and may have significant implications ranging from space weather to atmospheric chemistry. Chorus waves are the likely dominant cause of microburst precipitation, but important questions remain regarding the exact nature of the resonance generating the microbursts and the overall importance of the precipitation. These important questions are limited by lack of systematic coordination of simultaneous observations of causative waves in the magnetosphere and resulting precipitating particles at low altitudes. Increased funding for multi-spacecraft missions dedicated to answering these questions is critical.

Published
2022

12. On the Wave-Normal Distribution of Lightning-Generated Whistlers and Their Propagation Modes.

Author

Zhiyang Xia, Lunjin Chen, Horne, Richard B., Xu Liu, Jiabei He, and Bortnik, Jacob

Subjects
RAY tracing, GAUSSIAN distribution, ALTITUDES, IONOSPHERE
Abstract

Observations from Van Allen Probes are analyzed to obtain the statistical wave normal distribution of lightning-generated whistlers (LGWs). An automatic algorithm is developed to identify burst mode waveform data with LGW signals and analyze the wave polarization information for these LGW signals. The spatial distribution of the LGW occurrence and the probabilities of different propagation types demonstrate that most LGWs can be observed in the low L-shell region (L < 3), where the dominant propagation type is oblique outward. Parallel propagation dominates in the high L-shell region, but the LGW occurrence is very small. Additionally, a small group of oblique but inwardly propagating LGWs are observed at low altitudes (<0.2RE). A ray tracing simulation is performed not only to confirm predominant oblique and outward wave vectors in the vast region of the plasmasphere but also to verify the existence of these inward propagating LGW signals at low altitudes near the topside ionosphere. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Bounce Resonance Between Energetic Electrons and Magnetosonic Waves: A Parametric Study.

Author

Shujie Gu and Lunjin Chen

Subjects
RESONANCE, RESONANCE effect, ELECTROMAGNETIC waves, ELECTRON transport, PLASMA density, ELECTRONS
Abstract

Magnetosonic (MS) waves are electromagnetic emissions from a few to 100 Hz primarily confined near the magnetic equator both inside and outside the plasmasphere. Previous studies proved that MS waves can transport equatorially mirroring electrons from an equatorial pitch angle of 90° down to lower values by bounce resonance. However, the dependence of the bounce resonance effect on wave or background plasma parameters is still unclear. Here, we applied a test particle simulation to investigate electron transport coefficients, including diffusion and advection coefficients in energy and pitch angle, due to bounce resonance with MS waves. We investigate five wave field parameters, including wave frequency width, wave center frequency, latitudinal distribution width, wave normal angle root-mean-square of wave magnetic amplitude, and two background parameters, L-shell value and plasma density. We find different transport coefficient peaks resulting from different bounce resonance harmonics. Higher-order harmonic resonances exist, but the effect of fundamental resonance is much stronger. As the wave center frequency increases, higher-order harmonics start to dominate. With wave frequency width increasing, the energy range of effective bounce resonance broadens, but the effect itself weakens. The bounce resonance effect will increase when we decrease the wave normal angle, or increase the wave amplitude, latitudinal distribution width, L-shell value, and plasma density. The parametric study will advance our understanding of the favorable conditions of bounce resonance. [ABSTRACT FROM AUTHOR]

Published
2024
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16. The Angular Distribution of Whistler-Mode Chorus Wave Vector Directions from Van Allen Probes and MMS Observations

Author

David P. Hartley, Ivar Christopher, Lunjin Chen, Ondrej Santolik, Craig Kletzing, Matthew Argall, and Narges Ahmadi

Abstract

The dynamics of Earth's outer electron radiation belt is, in part, driven by interactions with whistler-mode chorus waves. Chorus can cause rapid acceleration of electrons up to relativistic energies, as well as drive precipitation of particles into the atmosphere causing both microbursts and diffuse aurora. Chorus can propagate in such a way that it crosses the plasmapause boundary and may contribute to the possible sources of plasmaspheric hiss, which itself can cause atmospheric losses of particles and the formation of the slot region between the inner and outer radiation belts. The direction of the wave vector relative to the background magnetic field is a key parameter for quantifying these processes, since it determines the propagation trajectory of the wave, and is required for calculating the resonance condition of the wave-particle interaction.The orientation of the wave vector is investigated using both survey mode data and high-resolution burst mode observations from the EMFISIS Waves instrument on the Van Allen Probes spacecraft. Spatial coverage beyond the Van Allen Probes orbit is provided by burst-mode observations from the FIELDS instrument suite on Magnetospheric Multiscale (MMS). The polar and azimuthal wave vector angles are considered using both spectral analysis, where the frequency-time structure can be resolved, and instantaneous values, which can be used to identify variations within individual chorus subpackets. We compare the results from each of these different timescales. Near strong plasma density gradients, such as those which occur on the boundaries of plasmaspheric plumes, we identify that the wave vector becomes more oblique than the general case where no density gradients are present. The obliquity of the wave vector is shown to directly relate to both the magnitude of the density gradient, and its proximity to the spacecraft.

Published
2023

37. UBER v1.0: a universal kinetic equation solver for radiation belts

Author

Zhiyang Xia, Peng Wang, L. Zheng, Lunjin Chen, Anthony A. Chan, and Xu Liu

Subjects
Physics, QE1-996.5, Stochastic differential equation, Nonlinear system, Numerical analysis, Coordinate system, Applied mathematics, Boundary (topology), Geology, Boundary value problem, Solver, Boltzmann equation
Abstract

Recent proceedings in radiation belt studies have proposed new requirements for numerical methods to solve the kinetic equations involved. In this article, we present a numerical solver that can solve the general form of the radiation belt Fokker–Planck equation and Boltzmann equation in arbitrarily provided coordinate systems and with user-specified boundary geometry, boundary conditions, and equation terms. The solver is based upon the mathematical theory of stochastic differential equations, whose computational accuracy and efficiency are greatly enhanced by specially designed adaptive algorithms and a variance reduction technique. The versatility and robustness of the solver are exhibited in four example problems. The solver applies to a wide spectrum of radiation belt modeling problems, including the ones featuring non-diffusive particle transport such as that arising from nonlinear wave–particle interactions.

Published
2021

44. Near‐Earth injection of MeV electrons associated with intense dipolarization electric fields: Van Allen Probes observations

Author

Lei Dai, Chi Wang, Suping Duan, Zhaohai He, John R. Wygant, Cynthia A. Cattell, Xin Tao, Zhenpeng Su, Craig Kletzing, Daniel N. Baker, Xinlin Li, David Malaspina, J. Bernard Blake, Joseph Fennell, Seth Claudepierre, Drew L. Turner, Geoffrey D. Reeves, Herbert O. Funsten, Harlan E. Spence, Vassilis Angelopoulos, Dennis Fruehauff, Lunjin Chen, Scott Thaller, Aaron Breneman, and Xiangwei Tang

Published
2015
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45. Whistler waves above the lower hybrid frequency in the ionosphere and their counterparts in the magnetosphere

Author

Zhiyang Xia, Lunjin Chen, Richard B. Horne, and Jacob Bortnik

Subjects
Geophysics, General Earth and Planetary Sciences
Abstract

In this study, we report the statistical properties of whistler mode low hybrid (LH) emissions in the ionosphere, which have structureless spectra with a lower frequency boundary that matches the variation of the local lower hybrid resonance frequency fLHR. A potential source for the low hybrid emissions is identified as the high-frequency plasmaspheric hiss (HFPH) in the magnetosphere. We use DEMETER and Van Allen Probes data to perform a statistical study of the wave power distribution of the LH emissions and HFPH. Both LH and HFPH emissions show a similar frequency range, a similar invariant magnetic latitude range, and have similar trends in magnetic local time (MLT) (stronger wave intensity on the dayside) and in the AE index (stronger wave intensity for higher AE condition). A ray tracing simulation is also performed to demonstrate the propagation of HFPH waves from the magnetosphere into the ionosphere as LH waves.

Published
2022

46. Ducted Chorus Waves Cause Sub‐Relativistic and Relativistic Electron Microbursts

Author

Lunjin Chen, Xiao‐Jia Zhang, Anton Artemyev, Vassilis Angelopoulos, Ethan Tsai, Colin Wilkins, and Richard B. Horne

Subjects
Geophysics, General Earth and Planetary Sciences
Abstract

During magnetospheric storms, radiation belt electrons are produced and then removed by collisions with the lower atmosphere on varying timescales. An efficient loss process is microbursts, strong, transient precipitation of electrons over a wide energy range, from tens of keV to sub-relativistic and relativistic energies (100s keV and above). However, the detailed generation mechanism of microbursts, especially over sub-relativistic and relativistic energies, remains unknown. Here we show that these energetic electron microbursts may be caused by ducted whistler-mode lower-band chorus waves. Using observations of equatorial chorus waves nearby low-altitude precipitation as well as data-driven simulations, we demonstrate that the observed microbursts are the result of resonant interaction of electrons with ducted chorus waves rather than nonducted ones. Revealing the physical mechanism behind the microbursts advances our understanding of radiation belt dynamics and its impact on the lower atmosphere and space weather.

Published
2022

49. Conjugate observation of magnetospheric chorus propagating to the ionosphere by ducting

Author

Yangyang Shen, A. D. Howarth, Anton Artemyev, Martin Connors, S. Tian, Xiao-Jia Zhang, Michael Hartinger, Richard B. Horne, Lunjin Chen, Jiashu Wu, H. Gordon James, Vassilis Angelopoulos, Christopher Cully, Jacob Bortnik, and Andrew W. Yau

Subjects
Physics, 010504 meteorology & atmospheric sciences, biology, Wave propagation, Chorus, Magnetosphere, Geophysics, biology.organism_classification, 01 natural sciences, 7. Clean energy, Physics::Geophysics, 13. Climate action, 0103 physical sciences, Physics::Space Physics, General Earth and Planetary Sciences, Atmospheric duct, Ionosphere, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Conjugate
Abstract

Whistler-mode chorus waves are critical for driving resonant scattering and loss of radiation belt relativistic electrons into the atmosphere. The resonant energies of electrons scattered by chorus waves increase at increasingly higher magnetic latitudes. Propagation of chorus waves to middle and high latitudes is hampered by wave divergence and Landau damping but is promoted otherwise if ducted by density irregularities. Although ducting theories have been proposed since the 1960’s, no conjugate observation of ducted chorus propagation from the equatorial magnetosphere to the ionosphere has been observed so far. Here we provide such an observation, for the first time, using conjugate spacecraft measurements. Ducted chorus waves maintain significant wave power upon reaching the ionosphere, which is confirmed by ray tracing simulations. Our results suggest that ducted chorus waves may be an important driver for relativistic electron precipitation.

Published
2021

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