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1. Relativistic and Ultra‐Relativistic Electron Bursts in Earth's Magnetotail Observed by Low‐Altitude Satellites

Author

Xiao‐Jia Zhang, Anton V. Artemyev, Xinlin Li, Harry Arnold, Vassilis Angelopoulos, Drew L. Turner, Mykhaylo Shumko, Andrei Runov, Yang Mei, and Zheng Xiang

Subjects
relativistic electrons, magnetic reconnection, Earth's magnetotail, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Earth's magnetotail, a night‐side region characterized by stretched magnetic field lines and strong plasma currents, is the primary site for the release of magnetic field energy and its transformation into plasma heating and kinetic energy plus charged particle acceleration during magnetic reconnection. In this study, we demonstrate that the efficiency of this acceleration can be sufficiently high to produce populations of relativistic and ultra‐relativistic electrons, with energies up to several MeV, which exceeds all previous theoretical and simulation estimates. Using data from the low‐altitude ELFIN and CIRBE CubeSats, we show multiple events of relativistic electron bursts within the magnetotail, far poleward of the outer radiation belt. These bursts are characterized by power‐law energy spectra and can be detected during even moderate substorms.

Published
2025
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2. Statistical Relationship Between Electron Flux and Resonant Chorus Wave Power Near the Flux Limit

Author

Emile Saint‐Girons, Xiao‐Jia Zhang, Didier Mourenas, Anton V. Artemyev, and Vassilis Angelopoulos

Subjects
radiation belts, energetic fluxes, Kennel‐Petschek limit, upper limit, maximum flux, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Electron precipitation by chorus whistler‐mode waves generated by the same electron population is expected to play an important role in the dynamics of the outer radiation belt, potentially setting a hard upper limit on trapped energetic electron fluxes. Here, we statistically analyze the relationship between equatorial electron fluxes and the power of mid‐latitude cyclotron‐resonant chorus waves precipitating these electrons, both inferred from ELFIN low‐altitude energy and pitch‐angle resolved electron flux measurements in 2020–2022. We provide clear evidence of a flux limitation coinciding with an exponential increase of precipitation. We statistically demonstrate that the actual inferred resonant wave power gains are well correlated with theoretical linear gains, as in the classical Kennel‐Petschek model, for moderately high linear gains and high fluxes. However, we also find a finite occurrence of very high fluxes, corresponding to resonant waves of moderate average amplitude, implying a softer, more dynamical upper limit than traditionally envisioned.

Published
2024
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3. The global mapping of electron precipitation and ionospheric conductance from whistler-mode chorus waves

Author

Dillon Gillespie, Hyunju Kim Connor, Qianli Ma, Xiao-Jia Zhang, Xiao-Chen Shen, Dogacan Ozturk, and Nigel P. Meredith

Subjects
diffuse auroral precipitation, chorus wave distributions, ionospheric conductance, conductance, wave driven precipitation, diffuse electron aurora, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Auroral precipitation is the second major energy source after solar irradiation that ionizes the Earth’s upper atmosphere. Diffuse electron aurora caused by wave-particle interaction in the inner magnetosphere (L < 8) takes over 60% of total auroral energy flux, strongly contributing to the ionospheric conductance and thus to the ionosphere-thermosphere dynamics. This paper quantifies the impact of chorus waves on the diffuse aurora and the ionospheric conductance during quiet, medium, and strong geomagnetic activities, parameterized by AE 300, respectively. Using chorus wave statistics and inner-magnetosphere plasma conditions from Timed History Events and Macroscale Interactions during Substorms (THEMIS) observations, we directly derive the energy spectrum of diffuse electron precipitation under quasi-linear theory. We then calculate the height-integrated conductance from the wave-driven aurora spectrum using the electron impact ionization model of Fang et al. (Geophys. Res. Lett., 2010, 37) and the MSIS atmosphere model. By utilizing Fang’s ionization model, the US Naval Research Laboratory Mass Spectrometer and Incoherent Scattar Radar (NRLMSISE-00) model from 2000s for the neutral atmosphere components, and the University of California, Los Angeles (UCLA) Full Diffusion Code, we improve upon the standard generalization of Maxwellian diffuse electron precipitation patterns and their resulting ionosphere conductance. Our study of global auroral precipitation and ionospheric conductance from chorus wave statistics is the first statistical model of its kind. We show that the total electron flux and conductance pattern from our results agree with those of Ovation Prime model over the pre-midnight to post-dawn sector as geomagnetic activity increases. Our study examines the relative contributions of upper band chorus (UBC) and lower band chorus wave (LBC) driven conductance in the ionosphere. We found LBC waves drove diffuse electron precipitation significantly more than UBC waves, however it is possible that THEMIS data may have underestimated the upper chorus band wave observations for magnetic latitudes below 65°.

Published
2024
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4. The Principal Role of Chorus Ducting for Night‐Side Relativistic Electron Precipitation

Author

Ning Kang, Anton V. Artemyev, Jacob Bortnik, Xiao‐Jia Zhang, and Vassilis Angelopoulos

Subjects
Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Night‐side chorus waves are often observed during plasma sheet injections, typically confined around the equator and thus potentially responsible for precipitation of ≲100 keV electrons. However, recent low‐altitude observations have revealed the critical role of chorus waves in scattering relativistic electrons on the night‐side. This study presents a night‐side relativistic electron precipitation event induced by chorus waves at the strong diffusion regime, as observed by the ELFIN CubeSats. Through event‐based modeling of wave propagation under ducted or unducted regimes, we show that a density duct is essential for guiding chorus waves to high latitudes with minimal damping, thus enabling the strong night‐side relativistic electron precipitation. These findings underline both the existence and the important role of density ducts in facilitating night‐side relativistic electron precipitation.

Published
2024
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5. Inclusion of Nonresonant Effects Into Quasi‐Linear Diffusion Rates for Electron Scattering by Electromagnetic Ion Cyclotron Waves

Author

Xiaofei Shi, Xin An, Anton Artemyev, Xiao‐Jia Zhang, Didier Mourenas, and Vassilis Angelopoulos

Subjects
Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Electromagnetic ion cyclotron (EMIC) waves are a key plasma mode affecting radiation belt dynamics. These waves are important for relativistic electron losses through scattering and precipitation into Earth's ionosphere. Although theoretical models of such resonant scattering predict a low‐energy cut‐off of ∼1 MeV for precipitating electrons, observations from low‐altitude spacecraft often show simultaneous relativistic and sub‐relativistic electron precipitation associated with EMIC waves. Recently, nonresonant electron scattering by EMIC waves has been proposed as a possible solution to the above discrepancy. We employ this model and a large database of EMIC waves to develop a universal treatment of electron interactions with EMIC waves, including nonresonant effects. We use the Green's function approach to generalize EMIC diffusion rates foregoing the need to modify existing codes or recompute empirical wave databases. Comparison with observations from the electron losses and fields investigation mission demonstrates the efficacy of the proposed method for explaining sub‐relativistic electron losses by EMIC waves.

Published
2024
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6. The Key Role of Magnetic Curvature Scattering in Energetic Electron Precipitation During Substorms

Author

Ying Zou, Xiao‐Jia Zhang, Anton V. Artemyev, Yangyang Shen, and Vassilis Angelopoulos

Subjects
energetic electron precipitation, substorm, wave‐particle interaction, magnetic field curvature scattering, ionization, TEC, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Energetic electron precipitation (EEP) during substorms significantly affects ionospheric chemistry and lower‐ionosphere (

Published
2024
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7. 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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8. Electron Precipitation Driven by EMIC Waves: Two Types of Energy Dispersion

Author

Veronika S. Grach, Anton V. Artemyev, Andrei G. Demekhov, Xiao‐Jia Zhang, Jacob Bortnik, and Vassilis Angelopoulos

Subjects
EMIC waves, wave‐particle interactions, radiation belts, precipitation, relativistic electrons, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Electromagnetic ion cyclotron (EMIC) waves can very rapidly and effectively scatter relativistic electrons into the atmosphere. EMIC‐driven precipitation bursts can be detected by low‐altitude spacecraft, and analysis of the fine structure of such bursts may reveal unique information about the near‐equatorial EMIC source region. In this study, we report, for the first time, observations of EMIC‐driven electron precipitation exhibiting energy, E, dispersion as a function of latitude (and hence L‐shell): two predominant categories exhibit dE/dL > 0 and dE/dL 0 is interpreted as due to an outward radial gradient of the equatorial magnetic field, likely produced by energetic ions freshly injected into the ring current (∼35% of the statistics). The observed energy dispersion of EMIC‐driven electron precipitation was reproduced in simulations.

Published
2024
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9. Red Line Diffuse‐Like Aurora Driven by Time Domain Structures Associated With Braking Magnetotail Flow Bursts

Author

Yangyang Shen, Jun Liang, Anton Artemyev, Vassilis Angelopoulos, Qianli Ma, Larry Lyons, Jiang Liu, Yukitoshi Nishimura, Xiao‐Jia Zhang, Ivan Vasko, and Donald L. Hampton

Subjects
time domain structures, diffuse aurora, discrete aurora, auroral precipitation, red line aurora, quasilinear diffusion, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Magnetotail earthward‐propagating fast plasma flows provide important pathways for magnetosphere‐ionosphere coupling. This study reexamines a flow‐related red‐line diffuse‐like aurora event previously reported by Liang et al. (2011, https://doi.org/10.1029/2010ja015867), utilizing THEMIS and ground‐based auroral observations from Poker Flat. We find that time domain structures (TDSs) within the flow bursts efficiently drive electron precipitation below a few keV, aligning with predominantly red‐line auroral intensifications in this non‐substorm event. The diffuse‐like auroras sometimes coexisted with or potentially evolved from discrete forms. We forward model red‐line diffuse auroras due to TDS‐driven precipitation, employing the time‐dependent TREx‐ATM auroral transport code. The good correlation (∼0.77) between our modeled and observed red line emissions underscores that TDSs are a primary driver of the red‐line diffuse‐like auroras, though whistler‐mode wave contributions are needed to fully explain the most intense red‐line emissions.

Published
2024
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10. Global Survey of Energetic Electron Precipitation at Low Earth Orbit Observed by ELFIN

Author

Murong Qin, Wen Li, Xiao‐Chen Shen, Vassilis Angelopoulos, Richard Selesnick, Luisa Capannolo, Qianli Ma, Anton Artemyev, and Xiao‐Jia Zhang

Subjects
electron precipitation, ELFIN, wave‐particle interaction, radiation belt, low Earth orbit, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract We statistically evaluate the global distribution and energy spectrum of electron precipitation at low‐Earth‐orbit, using unprecedented pitch‐angle and energy resolved data from the Electron Losses and Fields INvestigation CubeSats. Our statistical results indicate that during active conditions, the ∼63 keV electron precipitation ratio peaks at L > 6 at midnight, whereas the spatial distribution of precipitating energy flux peaks between the dawn and noon sectors. ∼1 MeV electron precipitation ratio peaks near midnight at L > ∼6 but is enhanced near dusk during active times. The energy spectrum of the precipitation ratio shows reversal points indicating energy dispersion as a function of L shell in both the slot region and at L > ∼6, consistent with hiss‐driven precipitation and current sheet scattering, respectively. Our findings provide accurate quantification of electron precipitation at various energies in a broad region of the Earth's magnetosphere, which is critical for magnetosphere‐ionosphere coupling.

Published
2024
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11. 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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13. Energetic Particle Precipitation in Sub‐Auroral Polarization Streams

Author

Anton V. Artemyev, Ying Zou, Xiao‐Jia Zhang, Xing Meng, and Vassilis Angelopoulos

Subjects
sub‐auroral polarization streams, relativistic electrons, EMIC waves, magnetosphere‐ionosphere coupling, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Sub‐auroral polarization streams (SAPS) are one of the most intense manifestations of magnetosphere‐ionosphere coupling. Magnetospheric energy transport to the ionosphere within SAPS is associated with Poynting flux and the precipitation of thermal energy (0.03–30 keV) plasma sheet particles. However, much less is known about the precipitation of high‐energy (≥50 keV) ions and electrons and their contribution to the low‐altitude SAPS physics. This study examines precipitation within one SAPS event using a combination of equatorial THEMIS and low‐altitude DMSP and ELFIN observations, which, jointly, cover from a few eV up to a few MeV energy range. Observed SAPS are embedding the ion isotropy boundary, which includes strong 300–1,000 keV ion precipitation. SAPS are associated with intense precipitation of relativistic electrons (≤3 MeV), well equatorward of the electron isotropy boundary. Such relativistic electron precipitation is likely due to electron scattering by electromagnetic ion cyclotron waves at the equator.

Published
2024
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15. Ionospheric Plasma Density Gradients Associated With Night‐Side Energetic Electron Precipitation

Author

Xiao‐Jia Zhang, Xing Meng, Anton V. Artemyev, Ying Zou, and Didier Mourenas

Subjects
ELFIN CubeSats, energetic electron precipitation, total electron content, whistler‐mode waves, EMIC waves, ionospheric density gradients, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Energetic electron precipitation from the equatorial magnetosphere into the atmosphere plays an important role in magnetosphere‐ionosphere coupling: precipitating electrons alter ionospheric properties, whereas ionospheric outflows modify equatorial plasma conditions affecting electromagnetic wave generation and energetic electron scattering. However, ionospheric measurements cannot be directly related to wave and energetic electron properties measured by high‐altitude, near‐equatorial spacecraft, due to large mapping uncertainties. We aim to resolve this by projecting low‐altitude measurements of energetic electron precipitation by ELFIN CubeSats onto total electron content (TEC) maps serving as a proxy for ionospheric density structures. We examine three types of precipitation on the nightside: precipitation of 500 keV) electron precipitation by EMIC waves. All three types of precipitation show distinct features in TEC horizontal gradients, and we discuss possible implications of these features.

Published
2023
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16. Bursty Energetic Electron Precipitation by High‐Order Resonance With Very‐Oblique Whistler‐Mode Waves

Author

Longzhi Gan, Anton Artemyev, Wen Li, Xiao‐Jia Zhang, Qianli Ma, Didier Mourenas, Vassilis Angelopoulos, Ethan Tsai, and Colin Wilkins

Subjects
precipitation, chorus, ELFIN, THEMIS, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Resonant interactions with whistler‐mode waves are one of the most important drivers for rapid energetic electron precipitation. In this letter, we study a conjunction event, where bursts of energetic electron precipitation (50–800 keV) with timescales of several seconds are observed by the twin ELFIN Cubesats at low Earth orbit, while very‐oblique intense whistler‐mode waves are observed by the Time History of Events and Macroscale Interactions during Substorms E satellite at the conjugate magnetic equator. Our observation‐constrained test‐particle simulations reveal that the electron precipitation, particularly above 100 keV, results from high‐order resonant scattering by the very‐oblique whistler‐mode waves. Our study provides the first direct evidence for high‐order resonance driven precipitation, explaining a bursty precipitation event. The results demonstrate that high‐order resonant scattering could be important, not only in long‐term diffusion models, but also in models of short timescale events.

Published
2023
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17. Modulation of Energetic Electron Precipitation Driven by Three Types of Whistler Mode Waves

Author

Xiao‐Chen Shen, Wen Li, Luisa Capannolo, Qianli Ma, Murong Qin, Anton V. Artemyev, Vassilis Angelopoulos, Xiao‐Jia Zhang, and Sheng Huang

Subjects
precipitation, whistler, hiss, chorus, magnetosphere, ionosphere, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Precipitation into the Earth's atmosphere due to pitch angle scattering by plasma waves has been recognized as one of the major loss mechanisms for energetic electrons. In this study, we quantitatively evaluate their roles in precipitating electrons during a conjunction event with modulated electron precipitation observed at low altitudes by Electron Loss and Fields INvestigation and three types of whistler mode waves (hiss, plume hiss, and chorus) measured near the equator by Time History of Events and Macroscale Interactions during Substorms. Electron precipitation was observed from ∼50 keV to

Published
2023
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18. Superfast precipitation of energetic electrons in the radiation belts of the Earth

Author

Xiao-Jia Zhang, Anton Artemyev, Vassilis Angelopoulos, Ethan Tsai, Colin Wilkins, Satoshi Kasahara, Didier Mourenas, Shoichiro Yokota, Kunihiro Keika, Tomoaki Hori, Yoshizumi Miyoshi, Iku Shinohara, and Ayako Matsuoka

Subjects
Science
Abstract

Energetic electron densities in the radiation belt increases during geomagnetic storms. Here, the authors show oblique whistler mode waves enhance electron losses and create strong fluxes of about 100 keV electrons precipitating into the atmosphere, that should be considered in radiation belt models.

Published
2022
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19. Transcripts related with ammonium use and effects of gibberellin on expressions of the transcripts responding to ammonium in two invasive and native Xanthium species

Author

Chang Zhang, Jia-Jun Luo, Jing-Bo Zuo, Zheng Zhang, Shi-Ting Wang, Xiao-Jia Zhang, Tian-Si Fu, and Yu-Long Feng

Subjects
ammonium, assimilation, gibberellin, transcriptome analysis, uptake, Plant culture, SB1-1110
Abstract

Soil nitrogen forms are important for exotic plant invasions. However, little effort has been made to study the molecular mechanisms underlying the utilization of different N forms in co-occurring invasive and native plants. The invasive plant Xanthium strumarium prefers nitrate relative to ammonium, and mainly invades nitrate-dominated environments, while it co-occurring native congener X. sibiricum prefers ammonium. Here, we addressed the genetic bases for the interspecific difference in ammonium use and the effects of gibberellin (GA). Twenty-six transcripts related with GA biosynthesis and ammonium utilization were induced by ammonium in X. sibiricum, while only ten in X. strumarium and none for ammonium uptake. XsiAMT1.1a, XsiGLN1.1 and XsiGLT1b may be crucial for the strong ability to absorb and assimilate ammonium in X. sibiricum. All tested transcripts were significantly up-regulated by GA1 and GA4 in X. sibiricum. XsiGA3OX1a, which was also induced by ammonium, may be involved in this regulation. Consistently, glutamine synthetase activity increased significantly with increasing ammonium-N/nitrate-N ratio for X. sibiricum, while decreased for X. strumarium. Our study is the first to determine the molecular mechanisms with which invasive and native plants use ammonium differently, contributing to understanding the invasion mechanisms of X. strumarium and its invasion habitat selection.

Published
2022
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20. Relativistic Electron Precipitation by EMIC Waves: Importance of Nonlinear Resonant Effects

Author

Veronika S. Grach, Anton V. Artemyev, Andrei G. Demekhov, Xiao‐Jia Zhang, Jacob Bortnik, Vassilis Angelopoulos, Rumi Nakamura, Ethan Tsai, Colin Wilkins, and Owen W. Roberts

Subjects
EMIC waves, wave‐particle interactions, force bunching, radiation belts, precipitation, Geophysics. Cosmic physics, QC801-809
Abstract

Abstract Relativistic electron losses in Earth's radiation belts are usually attributed to electron resonant scattering by electromagnetic waves. One of the most important wave modes for such scattering is the electromagnetic ion cyclotron (EMIC) mode. Within the quasi‐linear diffusion framework, the cyclotron resonance of relativistic electrons with EMIC waves results in very fast electron precipitation to the atmosphere. However, wave intensities often exceed the threshold for nonlinear resonant interaction, and such intense EMIC waves have been shown to transport electrons away from the loss cone due to the force bunching effect. In this study we investigate if this transport can block electron precipitation. We combine test particle simulations, low‐altitude observations of EMIC‐driven electron precipitation by the Electron Losses and Fields Investigations mission, and ground‐based EMIC observations. Comparing simulations and observations, we show that, despite the low pitch‐angle electrons being transported away from the loss cone, the scattering at higher pitch angles results in the loss cone filling and electron precipitation.

Published
2022
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21. Evidence of Electron Acceleration via Nonlinear Resonant Interactions with Whistler-mode Waves at Foreshock Transients

Author

Xiaofei Shi, Anton Artemyev, Vassilis Angelopoulos, Terry Liu, and Xiao-Jia Zhang

Subjects
Planetary bow shocks, Astrophysics, QB460-466
Abstract

Shock waves are sites of intense plasma heating and charged particle acceleration. In collisionless solar wind plasmas, such acceleration is attributed to shock drift or Fermi acceleration but also to wave–particle resonant interactions. We examine the latter for the case of electrons interacting with one of the most commonly observed wave modes in shock environments, the whistler mode. Such waves are particularly intense in dynamic, localized regions upstream of shocks, arising from the kinetic interaction of the shock with solar wind discontinuities. These regions, known as foreshock transients, are also sites of significant electron acceleration by mechanisms not fully understood. Using in situ observations of such transients in the Earth’s foreshock, we demonstrate that intense whistler-mode waves can resonate nonlinearly with >25 eV solar wind electrons and accelerate them to ∼100–500 eV. This acceleration is mostly effective for the 50–250 eV energy range, where the accelerated electron population exhibits a characteristic butterfly pitch-angle distribution consistent with theoretical predictions. Such nonlinear resonant acceleration is very fast, implying that this mechanism may be important for injecting suprathermal electrons of solar wind origin into the shock region, where they can undergo further, efficient shock-drift acceleration to even higher energies.

Published
2023
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22. Intense Whistler-mode Waves at Foreshock Transients: Characteristics and Regimes of Wave−Particle Resonant Interaction

Author

Xiaofei Shi, Terry Liu, Anton Artemyev, Vassilis Angelopoulos, Xiao-Jia Zhang, and Drew L. Turner

Subjects
Planetary bow shocks, Astrophysics, QB460-466
Abstract

Thermalization and heating of plasma flows at shocks result in unstable charged-particle distributions that generate a wide range of electromagnetic waves. These waves, in turn, can further accelerate and scatter energetic particles. Thus, the properties of the waves and their implication for wave−particle interactions are critically important for modeling energetic particle dynamics in shock environments. Whistler-mode waves, excited by the electron heat flux or a temperature anisotropy, arise naturally near shocks and foreshock transients. As a result, they can often interact with suprathermal electrons. The low background magnetic field typical at the core of such transients and the large wave amplitudes may cause such interactions to enter the nonlinear regime. In this study, we present a statistical characterization of whistler-mode waves at foreshock transients around Earth’s bow shock, as they are observed under a wide range of upstream conditions. We find that a significant portion of them are sufficiently intense and coherent (narrowband) to warrant nonlinear treatment. Copious observations of background magnetic field gradients and intense whistler wave amplitudes suggest that phase trapping, a very effective mechanism for electron acceleration in inhomogeneous plasmas, may be the cause. We discuss the implications of our findings for electron acceleration in planetary and astrophysical shock environments.

Published
2023
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23. 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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28. Electron Resonant Interaction With Coherent ULF Waves: Hamiltonian Approach.

Author

Artemyev, Anton, Xin An, Vainchtein, Dmitri, Rankin, Robert, Xuzhi Zhou, Li Li, and Xiao-Jia Zhang

Subjects
ELECTRON transport, ELECTRONS, MAGNETIC dipoles, ELECTRIC fields, MAGNETIC fields
Abstract

Electron resonant interaction with ultra-low-frequency (ULF) waves is considered to be a driver of electron radial transport in Earth's inner magnetosphere. Traditional concept of such interaction assumes the electron slow diffusive scattering by a broad-band ULF spectrum, but recent spacecraft observations reported a possibility for electrons to resonate nonlinearly with intense coherent ULF waves. This study proposes a theoretical model describing the main elements of such nonlinear resonant interactions. We implement a Hamiltonian approach to describe equatorial electron motion in a dipole magnetic field and electric ULF wavefield and demonstrate the ULF-electron interactions has two basic nonlinear resonant regimes: phase bunching and phase trapping. Finally, we discuss possible applications of the proposed theoretical approach and the importance of ULF-electron nonlinear resonances. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Comparative Study of Electric Currents and Energetic Particle Fluxes in a Solar Flare and Earth Magnetospheric Substorm

Author

Anton Artemyev, Ivan Zimovets, Ivan Sharykin, Yukitoshi Nishimura, Cooper Downs, James Weygand, Robyn Fiori, Xiao-Jia Zhang, Andrei Runov, Marco Velli, Vassilis Angelopoulos, Olga Panasenco, Christopher T. Russell, Yoshizumi Miyoshi, Satoshi Kasahara, Ayako Matsuoka, Shoichiro Yokota, Kunihiro Keika, Tomoaki Hori, Yoichi Kazama, Shiang-Yu Wang, Iku Shinohara, and Yasunobu Ogawa

Published
2021
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34. Electron acceleration by intense whistler-mode waves at foreshock transients

Author

Xiaofei Shi, Anton Artemyev, Vassilis Angelopoulos, Terry Liu, and Xiao-Jia Zhang

Abstract

The shock wave is a primary interface for plasma heating and charged particle acceleration. In collisionless solar wind plasma, such acceleration is attributed to the wave-particle resonant interactions. This letter focuses on electron acceleration by one of the most widespread high-frequency electromagnetic wave emissions, whistler-mode waves. Using spacecraft observations of the Earth's foreshock transient, we demonstrate that intense whistler-mode waves may resonate nonlinearly with $\sim 10-100$eV solar wind electrons and accelerate them to $\sim 100-500$eV. Accelerated electron population has a butterfly pitch-angle distribution, in agreement with theoretical predictions. The presented evidence of the efficiency of nonlinear resonant acceleration suggests that this mechanism may play an important role in solar wind electron injection into the shock-drift acceleration.

Published
2023
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36. Diffusive scattering of energetic electrons by intense whistler-mode waves in an inhomogeneous plasma

Author

Viktor A. Frantsuzov, Anton V. Artemyev, Xiao-Jia Zhang, Oliver Allanson, Pavel I. Shustov, and Anatoli A. Petrukovich

Subjects
Condensed Matter Physics
Abstract

Electron resonant interactions with electromagnetic whistler-mode waves play an important role in electron flux dynamics in various space plasma systems: planetary radiation belts, bow shocks, solar wind and magnetic reconnection regions. Two key wave characteristics determining the regime of wave–particle interactions are the wave intensity and the wave coherency. The classical quasi-linear diffusion approach describes well electron diffusion by incoherent and low-amplitude waves, whereas the nonlinear resonant models describe electron phase bunching and trapping by highly coherent intense waves. This study is devoted to the investigation of the regime of electron resonant interactions with incoherent but intense waves. Although this regime is characterized by electron diffusion, we show that diffusion rates scale linearly with the wave amplitude,$D\propto B_w$, in contrast to the quasi-linear diffusion scaling$D_{QL}\propto B_w^2$. Using observed wave amplitude distributions, we demonstrate that the quasi-linear diffusion model significantly overestimates electron scattering by incoherent, but intense whistler-mode waves. We discuss the results obtained in the context of simulations of long-term electron flux dynamics in space plasma systems.

Published
2023
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38. Temporal Scales of Electron Precipitation Driven by Whistler-Mode Waves

Author

Xiao‐Jia Zhang, Vassilis Angelopoulos, Anton Artemyev, Didier Mourenas, Oleksiy Agapitov, Ethan Tsai, and Colin Wilkins

Subjects
Geophysics, Physics - Space Physics, Space and Planetary Science, FOS: Physical sciences, Space Physics (physics.space-ph)
Abstract

Electron resonant scattering by whistler-mode waves is one of the most important mechanisms responsible for electron precipitation to the Earth's atmosphere. We investigate temporal and spatial scales of such precipitation with measurements from the two low-altitude ELFIN CubeSats. We compare the variations in energetic electron precipitation at the same L-shells but on successive data collection orbit tracks by the two ELFIN satellites. Variations seen at the smallest inter-satellite separations are likely associated with whistler-mode chorus elements or with the scale of chorus wave packets (0.1 - 1 s in time and 100 km in space at the equator). Variations between precipitation L-shell profiles at intermediate inter-satellite separations are likely associated with whistler-mode wave power modulations by ultra-low frequency (ULF) waves, i.e., with the wave source region (from a few to tens of seconds to a few minutes in time and 1000km in space at the equator). During these two types of variations, consecutive crossings are associated with precipitation L-shell profiles very similar to each other. Therefore the spatial and temporal variations at those scales do not change the net electron loss from the outer radiation belt. Variations at the largest range of inter-satellite separations, several minutes to more than 10 min, are likely associated with mesoscale equatorial plasma structures that are affected by convection (at minutes to tens of minutes temporal variations and [1000,10000]km spatial scales). The latter type of variations results in appreciable changes in the precipitation L-shell profiles and can significantly modify the net electron losses during successive tracks.

Published
2022

39. Intense whistler-mode waves at foreshock transients: characteristics and regimes of wave-particle resonant interaction

Author

Xiaofei Shi, Terry Liu, Anton Artemyev, Vassilis Angelopoulos, Xiao-Jia Zhang, and Drew L. Turner

Subjects
Plasma Physics (physics.plasm-ph), Earth and Planetary Astrophysics (astro-ph.EP), Physics - Space Physics, Space and Planetary Science, FOS: Physical sciences, Astronomy and Astrophysics, Space Physics (physics.space-ph), Physics - Plasma Physics, Astrophysics - Earth and Planetary Astrophysics
Abstract

Thermalization and heating of plasma flows at shocks result in unstable charged-particle distributions which generate a wide range of electromagnetic waves. These waves, in turn, can further accelerate and scatter energetic particles. Thus, the properties of the waves and their implication for wave-particle interactions are critically important for modeling energetic particle dynamics in shock environments. Whistler-mode waves, excited by the electron heat flux or a temperature anisotropy, arise naturally near shocks and foreshock transients. As a result, they can often interact with supra-thermal electrons. The low background magnetic field typical at the core of such transients and the large wave amplitudes may cause such interactions to enter the nonlinear regime. In this study, we present a statistical characterization of whistler-mode waves at foreshock transients around Earth bow shock, as they are observed under a wide range of upstream conditions. We find that a significant portion of them are sufficiently intense and coherent to warrant nonlinear treatment. Copious observations of background magnetic field gradients and intense whistler wave amplitudes suggest that phase trapping, a very effective mechanism for electron acceleration in inhomogeneous plasmas, may be the cause. We discuss the implications of our findings for electron acceleration in planetary and astrophysical shock environments., Submitted to APJ

Published
2022

43. Genome-wide identification of WD40 genes reveals a functional diversification of COP1-like genes in Rosaceae

Author

Dong-Mei Yu, Xiao-Dong Jiang, Jin-Yong Hu, Yi-Bo Sun, Xue Dong, Wei-Hua Cui, Xiao-Jia Zhang, Dan Wang, Mi-Cai Zhong, and Jianghua Chen

Subjects
0106 biological sciences, 0301 basic medicine, Ubiquitin-Protein Ligases, Rosaceae, Arabidopsis, Plant Science, Genes, Plant, Rosa, 01 natural sciences, Genome, Chromosomes, Plant, Domestication, 03 medical and health sciences, Gene Expression Regulation, Plant, Gene Duplication, Gene duplication, Genetics, Amino Acid Sequence, Gene, Phylogeny, Plant Proteins, biology, General Medicine, Plants, Genetically Modified, biology.organism_classification, 030104 developmental biology, Evolutionary biology, Regulatory sequence, Photomorphogenesis, Tandem exon duplication, Agronomy and Crop Science, Genome, Plant, Function (biology), 010606 plant biology & botany
Abstract

Genome-wide identification of WD40-like genes reveals a duplication of COP1-like genes, one of the key players involved in regulation of flowering time and photomorphogenesis, with strong functional diversification in Rosaceae. WD40 proteins play crucial roles in a broad spectrum of developmental and physiological processes. Here, we conducted a systematic characterization of this family of genes in Rosa chinensis 'Old Blush' (OB), a founder genotype for modern rose domestication. We identified 187 rose WD40 genes and classified them into 5 clusters and 15 subfamilies with 11 of RcWD40s presumably generated via tandem duplication. We found RcWD40 genes were expressed differentially following stages of vegetative and reproductive development. We detected a duplication of CONSTITUTIVE PHOTOMORPHOGENIC1-like genes in rose (RcCOP1 and RcCOP1L) and other Rosaceae plants. Featuring a distinct expression pattern and a different profile of cis-regulatory-elements in the transcriptional regulatory regions, RcCOP1 seemed being evolutionarily conserved while RcCOP1L did not dimerize with RcHY5 and RcSPA4. Our data thus reveals a functional diversification of COP1-like genes in Rosacaeae plants, and provides a valuable resource to explore the potential function and evolution of WD40-like genes in Rosaceae plants.

Published
2020
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44. Development Direction of Pipeline Corrosion Research on Oil Refining and Chemical Enterprises

Author

Xiao Jia Zhang, Rui Wang, and Shang Yu Yang

Subjects
010302 applied physics, Materials science, Petroleum engineering, Mechanical Engineering, Oil refinery, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Pipeline (software), Corrosion, Mechanics of Materials, 0103 physical sciences, General Materials Science, 0210 nano-technology
Abstract

The corrosion behavior of refinery due to severe corrosive environment was investigated in the present study, and the analysis was focused on the guiding of the corrosion into a site where is near the ground, easy to change, have low risk and so on. The corrosion parts were analyzed to study the influences of the corrosion pipe in the whole systems. Some suggestions were proposed to choose the corrosion site that can happened. By using the developed method in this study the low risk position of pipeline as a sacrificial location can be found, and then taking it as the priority corrosion place under the control of switchable subline. It is therefore to shut down for maintenance of whole pipeline, and to easily replace the corrosion parts without stop all. The serious corrosion of refining pipeline system can consequently be reduced and removed, thereby to make the long-cycle operation of refining factory be realized.

Published
2020
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48. 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
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49. Tens to hundreds of keV electron precipitation driven by kinetic Alfvén waves during an electron injection

Author

Yangyang Shen, Anton V. Artemyev, Xiao‐Jia Zhang, Vassilis Angelopoulos, Ivan Vasko, Drew Turner, Ethan Tsai, Colin Wilkins, James M. Weygand, Christopher T. Russell, Robert E. Ergun, and Barbara L. Giles

Subjects
Plasma Physics (physics.plasm-ph), Geophysics, Physics - Space Physics, Space and Planetary Science, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, Physics - Fluid Dynamics, Physics - Plasma Physics, Space Physics (physics.space-ph)
Abstract

Electron injections are critical processes associated with magnetospheric substorms, which deposit significant electron energy into the ionosphere. Although wave scattering of $, 25 pages, 5 figures, with supporting information, the manuscript has been accepted for publication by JGR space physics

Published
2022
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50. Statistical Analysis of Concurrent Electron Cyclotron Harmonic and Whistler Waves Driven by ULF Waves.

Author

Waheed, Abdul, Bashir, M. Fraz, Artemyev, Anton V., and Xiao-Jia Zhang

Subjects
ELECTRONS, RADIATION belts, ATMOSPHERE, PLASMA waves, STATISTICS, CYCLOTRONS
Abstract

Plasma sheet electron precipitation to the diffuse aurora is one of the primary mechanisms of magnetospheric energy transport to the Earth's atmosphere. Such precipitation is provided by electron resonant interactions with electron cyclotron harmonics (ECH) and whistler-mode waves in the near-Earth plasma sheet. ECH and whistler-mode wave generation is traditionally attributed to two main sources of free energy: the loss-cone anisotropy and the temperature anisotropy due to transverse electron heating during earthward convection or plasma sheet injections. This paper considers a third free energy source for ECH and whistlermode wave generation--the electron distribution modulation by compressional ultra-low-frequency (ULF) waves. We conduct statistics of ECH and whistler-mode wave bursts associated with ULF waves and show that: (a) such bursts are mostly observed on the dawn flank, (b) 83% of events show a correlation between ECH and whistler-mode bursts, and the rest 17% show anti-correlation, (c) ECH and whistler-mode wave intensities are comparable with those observed around the night-side injection region. We investigate the main characteristics of ECH and whistler-mode waves modulated by ULF waves and provide an empirical model for these characteristics. This model can be directly incorporated into simulation frameworks, so as to include these ULF-modulated wave bursts in simulations of the magnetosphere-ionosphere coupling and radiation belt dynamics. [ABSTRACT FROM AUTHOR]

Published
2023
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