Your search keyword '"Artemyev, A."' showing total 5,490 results

1. Streamer-like red line diffuse auroras driven by time domain structures and ECH waves associated with a plasma injection and braking ion flows

Author

Shen, Yangyang, Zhang, Xu, Liang, Jun, Artemyev, Anton, Angelopoulos, Vassilis, Spanswick, Emma, Lyons, Larry, and Nishimura, Yukitoshi

Subjects

Physics - Space Physics, Astrophysics - Earth and Planetary Astrophysics, Physics - Geophysics, Physics - Plasma Physics

Abstract

Auroral streamers are important meso-scale processes of dynamic magnetosphere-ionosphere coupling, typically studied using imagers sensitive to energetic (>1 keV) electron precipitation, such as all-sky imagers (ASIs). This paper reports streamer-like red-line auroras, representing low-energy (<1 keV) precipitation, observed poleward of a black aurora and an auroral torch. These red-line auroras were associated with a magnetospheric electron injection and braking ion flows. Observations were made using the THEMIS spacecraft and ground-based imagers, including the ASI, REGO, and meridian scanning photometer (MSP) at Fort Smith. We identify plasma sheet electron pitch-angle scattering by time-domain structures (TDSs) and electron cyclotron harmonics (ECH) waves as the driver of these red-line auroras, because of (1) a strong correlation (~0.9) between observed red-line intensities and precipitating fluxes; (2) consistent red-line intensities from auroral transport code forward modeling, and (3) consistent precipitation characteristic energies from MSP optical inference and quasi-linear estimates., Comment: 18 pages, 3 figures, to be submitted to Geophysical Research Letters

Published

2025

2. Compound electron acceleration at planetary foreshocks.

Author

Shi, Xiaofei, Artemyev, Anton, Angelopoulos, Vassilis, Liu, Terry, and Wilson Iii, Lynn

Abstract

Shock waves, the interface of supersonic and subsonic plasma flows, are the primary region for charged particle acceleration in multiple space plasma systems, including Earths bow shock, which is readily accessible for in-situ measurements. Spacecraft frequently observe relativistic electron populations within this region, characterized by energy levels surpassing those of solar wind electrons by a factor of 10,000 or more. However, mechanisms of such strong acceleration remain elusive. Here we use observations of electrons with energies up to 200 kiloelectron volts and a data-constrained model to reproduce the observed power-law electron spectrum and demonstrate that the acceleration by more than 4 orders of magnitude is a compound process including a complex, multi-step interaction between more commonly known mechanisms and resonant scattering by several distinct plasma wave modes. The proposed model of electron acceleration addresses a decades-long issue of the generation of energetic (and relativistic) electrons at planetary plasma shocks. This work may further guide numerical simulations of even more effective electron acceleration in astrophysical shocks.

Published

2025

3. Night-Side Relativistic Electron Precipitation Bursts in the Outer Radiation Belt: Insights from ELFIN and THEMIS

Author

Lu, Xi, Zhang, Xiao-Jia, Artemyev, Anton V., Angelopoulos, Vassilis, and Bortnik, Jacob

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Electromagnetic whistler-mode waves play a crucial role in the acceleration and precipitation of radiation belt electrons. Statistical surveys of wave characteristics suggest that these waves should preferentially scatter and precipitate relativistic electrons on the day side. However, the night-side region is expected to be primarily associated with electron acceleration. The recent low-altitude observations reveal relativistic electron precipitation in the night-side region. In this paper, we present statistical surveys of night-side relativistic electron losses due to intense precipitation bursts. We demonstrate that such bursts are associated with storm time substorm injections and are likely related to relativistic electron scattering by ducted whistler-mode waves. We also speculate on the role of injections in creating conditions favorable for relativistic electron precipitation.

Published

2024

4. A Localized Burst of Relativistic Electrons in Earth's Plasma Sheet: Low- and High-Altitude Signatures During a Substorm

Author

Shumko, M., Turner, D. L., Ukhorskiy, A. Y., Cohen, I. J., Stephens, G. K., Artemyev, A., Zhang, X., Wilkins, C., Tsai, E., Gabrielse, C., Raptis, S., Sitnov, M., and Angelopoulos, V.

Subjects

Physics - Space Physics

Abstract

Earth's magnetotail, and the plasma sheet embedded in it, is a highly dynamic region that is coupled to both the solar wind and to the inner magnetosphere. As a consequence of this coupling, the plasma sheet undergoes explosive energy releases in the form of substorms. One consequence of this energy release is heating of thermal electrons and acceleration of energetic (non-thermal) electrons. The upper-energy limit as well as the spatial scale size of the electron acceleration regions remain mysteries in magnetotail physics because current missions can effectively only offer us a single-point glimpse into the numerous magnetotail phenomena ranging from electron- to global-scales. These energetic electrons can provide a significant source of seed electrons for the Van Allen Radiation belts. Here we use a unique approach to study relativistic plasma sheet electron acceleration. We combine high-altitude Magnetospheric Multiscale (MMS) mission observations with low-altitude Electron Losses and Fields Investigation (ELFIN) observations, to quantify the upper-energy extent and radial scale of a burst of plasma sheet electrons that mapped to 33 Earth radii. The plasma sheet locally accelerated an intense mesoscale burst of 3 MeV electrons -- far higher and more intense than the outer Van Allen radiation belt -- and scattered them into the atmospheric loss cone. High-altitude observations Earthward of the burst at 17 Earth radii showed only the usual substorm activity signatures -- demonstrating that this burst was 1) intense, 2) localized to the far magnetotail, and 3) likely accelerated by a very efficient and rapid mechanism.

Published

2024

5. Nonlinear resonant interactions of radiation belt electrons with intense whistler-mode waves

Author

Artemyev, A. V., Mourenas, D., Zhang, X. -J., Agapitov, O., Neishtadt, A. I., Vainchtein, D. L., Vasiliev, A. A., Zhang, X., Ma, Q., Bortnik, J., and Krasnoselskikh, V. V.

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

The dynamics of the Earth's outer radiation belt, filled by energetic electron fluxes, is largely controlled by electron resonant interactions with electromagnetic whistler-mode waves. The most coherent and intense waves resonantly interact with electrons nonlinearly, and the observable effects of such nonlinear interactions cannot be described within the frame of classical quasi-linear models. This paper provides an overview of the current stage of the theory of nonlinear resonant interactions and discusses different possible approaches for incorporating these nonlinear interactions into global radiation belt simulations. We focused on observational properties of whistler-mode waves and theoretical aspects of electron nonlinear resonant interactions between such waves and energetic electrons.

Published

2024

6. Magnetospheric Control of Ionospheric TEC Perturbations via Whistler-Mode and ULF Waves.

Author

Shen, Yangyang, Verkhoglyadova, Olga, Artemyev, Anton, Hartinger, Michael, Angelopoulos, Vassilis, Shi, Xueling, and Zou, Ying

Subjects

ionosphere irregularities, ionosphere scintillation, magnetosphere ionosphere coupling, particle precipitation, total electron content, whistler‐mode waves

Abstract

The weakly ionized plasma in the Earths ionosphere is controlled by a complex interplay between solar and magnetospheric inputs from above, atmospheric processes from below, and plasma electrodynamics from within. This interaction results in ionosphere structuring and variability that pose major challenges for accurate ionosphere prediction for global navigation satellite system (GNSS) related applications and space weather research. The ionospheric structuring and variability are often probed using the total electron content (TEC) and its relative perturbations (dTEC). Among dTEC variations observed at high latitudes, a unique modulation pattern has been linked to magnetospheric ultra-low-frequency (ULF) waves, yet its underlying mechanisms remain unclear. Here using magnetically conjugate observations from the THEMIS spacecraft and a ground-based GPS receiver at Fairbanks, Alaska, we provide direct evidence that these dTEC modulations are driven by magnetospheric electron precipitation induced by ULF-modulated whistler-mode waves. We observed peak-to-peak dTEC amplitudes reaching ∼ 0.5 TECU (1 TECU is equal to 10 6 electrons/ m 2 ) with modulations spanning scales of ∼ 5-100 km. The cross-correlation between our modeled and observed dTEC reached ∼ 0.8 during the conjugacy period but decreased outside of it. The spectra of whistler-mode waves and dTEC also matched closely at ULF frequencies during the conjugacy period but diverged outside of it. Our findings elucidate the high-latitude dTEC generation from magnetospheric wave-induced precipitation, addressing a significant gap in current physics-based dTEC modeling. Theses results thus improve ionospheric dTEC prediction and enhance our understanding of magnetosphere-ionosphere coupling via ULF waves.

Published

2024

7. Variation of Whistler-Mode Wave Characteristics Along Magnetic Field Lines: Comparison of Near-Equatorial THEMIS and Middle-Latitude ERG Observations

Author

Kadan, Sophie, Zhang, Xiao-Jia, Artemyev, Anton, Miyoshi, Yoshizumi, Matsuoka, Ayako, Kasahara, Yoshiya, Matsuda, Shoya, Hori, Tomoaki, Teramoto, Mariko, Yamamoto, Kazuhiro, and Shinohara, Iku

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

The latitudinal distribution of whistler-mode wave intensity plays a crucial role in determining the efficiency and energy of electrons scattered by these waves in the outer radiation belt. Traditionally, this wave property has mostly been derived from statistical measurements of off-equatorial spacecraft, which collect intensity data at various latitudes under different geomagnetic conditions and at different times. In this study we examine a set of events captured by both the near-equatorial THEMIS spacecraft and the off-equatorial ERG spacecraft. Specifically, we compare the whistler-mode wave intensity from THEMIS and ERG measurements at the same MLT and time sectors. Similar wave spectrum characteristics confirm that THEMIS and ERG indeed observed the same wave activity. However, upon closer examination of the wave intensity variations, we identify two distinct categories of events: those that follow the statistically predicted variations in wave intensity along magnetic latitudes, and those that exhibit rapid wave intensity decay away from the equatorial plane. We analyze main characteristics of events from both categories and discuss possible implications of our analysis for radiation belt models.

Published

2024

8. Statistical Characteristics of the Proton Isotropy Boundary

Author

Wilkins, Colin, Angelopoulos, Vassilis, Artemyev, Anton, Runov, Andrei, Zhang, Xiao-Jia, Liu, Jiang, and Tsai, Ethan

Subjects

Physics - Space Physics, Physics - Geophysics, Physics - Plasma Physics

Abstract

Using particle data from the ELFIN satellites, we present a statistical study of 284 proton isotropy boundary events on the nightside magnetosphere, characterizing their occurrence and distribution in local time, latitude (L-shell), energy, and precipitating energy flux, as a function of geomagnetic activity. For a given charged particle species and energy, its isotropy boundary (IB) is the magnetic latitude poleward of which persistently isotropic pitch-angle distributions ($J_{prec}/J_{perp}\sim 1$) are first observed to occur. This isotropization is interpreted as resulting from magnetic field-line curvature (FLC) scattering in the equatorial magnetosphere. We find that proton IBs are observed under all observed activity levels, spanning 16 to 05 MLT with $\sim$100% occurrence between 19 and 03 MLT, trending toward 60% at dawn/dusk. These results are also compared with electron IB properties observed using ELFIN, where we find similar trends across local time and activity, with the onset in $\geq$50 keV proton IB occurring on average 2 L-shells lower, and providing between 3 and 10 times as much precipitating power. Proton IBs typically span $64^\circ$-$66^\circ$ in magnetic latitude (5-6 in L-shell), corresponding to the outer edge of the ring current, tending toward lower IGRF latitudes as geomagnetic activity increases. The IBs were found to commonly occur 0.3-2.1 Re beyond the plasmapause. Proton IBs typically span $<$50 keV to $\sim$1 MeV in energy, maximizing near 22 MLT, and decreasing to a typical upper limit of 300-400 keV toward dawn and dusk, with peak observed isotropic energy increasing by $\sim$500 keV during active intervals. These results suggest that FLC in the vicinity of IBs can provide a substantial depletion mechanism for energetic protons, with the total nightside precipitating power from FLC-scattering found to be on the order of 100 MW, at times $\geq$10 GW.

Published

2024

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

Author

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

Subjects

Physics - Space Physics, Physics - Plasma Physics

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

2024

10. 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

11. Picturing global substorm dynamics in the magnetotail using low-altitude ELFIN measurements and data mining-based magnetic field reconstructions

Author

Shi, Xiaofei, Stephens, Grant K., Artemyev, Anton V., Sitnov, Mikhail I., and Angelopoulos, Vassilis

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

A global reconfiguration of the magnetotail characterizes substorms. Current sheet thinning, intensification, and magnetic field stretching are defining features of the substorm growth phase and their spatial distributions control the timing and location of substorm onset. Presently, sparse in-situ observations cannot resolve these distributions. A promising approach is to use new substorm magnetic field reconstruction methods based on data mining, termed SST19. Here we compare the SST19 reconstructions to low-altitude ELFIN measurements of energetic particle precipitations to probe the radial profile of the equatorial magnetic field curvature during a 19~August 2022 substorm. ELFIN and SST19 yield a consistent dynamical picture of the magnetotail during the growth phase and capture expected features such as the formation of a thin current sheet and its earthward motion. Furthermore, they resolve a V-like pattern of isotropic electron precipitation boundaries in the time-energy plane, consistent with earlier observations but now over a broad energy range.

Published

2024

12. MEDeA: Multi-view Efficient Depth Adjustment

Author

Artemyev, Mikhail, Vorontsova, Anna, Sokolova, Anna, and Limonov, Alexander

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

The majority of modern single-view depth estimation methods predict relative depth and thus cannot be directly applied in many real-world scenarios, despite impressive performance in the benchmarks. Moreover, single-view approaches cannot guarantee consistency across a sequence of frames. Consistency is typically addressed with test-time optimization of discrepancy across views; however, it takes hours to process a single scene. In this paper, we present MEDeA, an efficient multi-view test-time depth adjustment method, that is an order of magnitude faster than existing test-time approaches. Given RGB frames with camera parameters, MEDeA predicts initial depth maps, adjusts them by optimizing local scaling coefficients, and outputs temporally-consistent depth maps. Contrary to test-time methods requiring normals, optical flow, or semantics estimation, MEDeA produces high-quality predictions with a depth estimation network solely. Our method sets a new state-of-the-art on TUM RGB-D, 7Scenes, and ScanNet benchmarks and successfully handles smartphone-captured data from ARKitScenes dataset.

Published

2024

13. Omnidirectional Energetic Electron Fluxes from 150 km to 20,000 km: an ELFIN-Based Model

Author

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

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

The strong variations of energetic electron fluxes in the Earth's inner magnetosphere are notoriously hard to forecast. Developing accurate empirical models of electron fluxes from low to high altitudes at all latitudes is therefore useful to improve our understanding of flux variations and to assess radiation hazards for spacecraft systems. In the present work, energy- and pitch-angle-resolved precipitating, trapped, and backscattered electron fluxes measured at low altitude by Electron Loss and Fields Investigation (ELFIN) CubeSats are used to infer omnidirectional fluxes at altitudes below and above the spacecraft, from 150 km to 20,000 km, making use of adiabatic transport theory and quasi-linear diffusion theory. The inferred fluxes are fitted as a function of selected parameters using a stepwise multivariate optimization procedure, providing an analytical model of omnidirectional electron flux along each geomagnetic field line, based on measurements from only one spacecraft in low Earth orbit. The modeled electron fluxes are provided as a function of $L$-shell, altitude, energy, and two different indices of past substorm activity, computed over the preceding 4 hours or 3 days, potentially allowing to disentangle impulsive processes (such as rapid injections) from cumulative processes (such as inward radial diffusion and wave-driven energization). The model is validated through comparisons with equatorial measurements from the Van Allen Probes, demonstrating the broad applicability of the present method. The model indicates that both impulsive and time-integrated substorm activity partly control electron fluxes in the outer radiation belt and in the plasma sheet.

Published

2024

14. Identification of coupled Landau and anomalous resonances in space plasmas

Author

Li, Jing-Huan, Zhou, Xu-Zhi, Liu, Zhi-Yang, Wang, Shan, Artemyev, Anton V., Omura, Yoshiharu, Zhang, Xiao-Jia, Li, Li, Yue, Chao, Zong, Qiu-Gang, Pollock, Craig, Le, Guan, and Burch, James L.

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Wave-particle resonance, a ubiquitous process in the plasma universe, occurs when resonant particles observe a constant wave phase to enable sustained energy transfer. Here, we present spacecraft observations of simultaneous Landau and anomalous resonances between oblique whistler waves and the same group of protons, which are evidenced, respectively, by phase-space rings in parallel-velocity spectra and phase-bunched distributions in gyro-phase spectra. Our results indicate the coupling between Landau and anomalous resonances via the overlapping of the resonance islands., Comment: 13 pages, 4 figures and supplementary material

Published

2024

15. Resonance of low-frequency electromagnetic and ion-sound modes in the solar wind

Author

Vasko, I. Y., Mozer, F. S., Bowen, T., Verniero, J., An, X., Artemyev, A. V., Bonnell, J. W., Halekas, J., and Kuzichev, I. V.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics, 82D10

Abstract

Parker Solar Probe measurements have recently shown that coherent fast magnetosonic and Alfv\'{e}n ion-cyclotron waves are abundant in the solar wind and can be accompanied by higher-frequency electrostatic fluctuations. In this letter we reveal the nonlinear process capable of channelling the energy of low-frequency electromagnetic to higher-frequency electrostatic fluctuations observed aboard Parker Solar Probe. We present Hall-MHD simulations demonstrating that low-frequency electromagnetic fluctuations can resonate with the ion-sound mode, which results in steepening of plasma density fluctuations, electrostatic spikes and harmonics in the electric field spectrum. The resonance can occur around the wavenumber determined by the ratio between local sound and Alfv\'{e}n speeds, but only in the case of {\it oblique} propagation to the background magnetic field. The resonance wavenumber, its width and steepening time scale are estimated, and all indicate that the revealed two-wave resonance can frequently occur in the solar wind. This process can be a potential channel of energy transfer from cyclotron resonant ions producing the electromagnetic fluctuations to Landau resonant ions and electrons absorbing the energy of the higher-frequency electrostatic fluctuations., Comment: 13 pages, 5 figures

Published

2024

16. Census Results of the Northern Lapwing (Vanellus vanellus, Charadriformes) in the Olonets Fields, Karelia, Northwestern Russia, in 1993–2023

Author

Simonov, S. A., Artemyev, A. V., Lapshin, N. V., Tolstoguzov, A. O., and Matantseva, M. V.

Published

2024

17. Amplification of the Surface-Enhanced Raman Scattering Signal from a Monolayer of Organic Molecules in Sandwich Structures Containing Plasmonic Silver Nanoplates

Author

Malakhovsky, P. O., Ramanenka, A. A., and Artemyev, M. V.

Published

2024

18. Atomic Molecular Representations of Erbium Powders Annealed by Thermal Doping of Porous Silicon

Author

Khamzin, E. H., Nefedov, S. A., Artemyev, D. N., and Latukhina, N. V.

Published

2024

19. Beam-driven Electron Cyclotron Harmonic and Electron Acoustic Waves as Seen in Particle-In-Cell Simulations

Author

Zhang, Xu, An, Xin, Angelopoulos, Vassilis, Artemyev, Anton, Zhang, Xiao-Jia, and Jia, Ying-Dong

Subjects

Physics - Plasma Physics, Physics - Space Physics

Abstract

Recent study has demonstrated that electron cyclotron harmonic (ECH) waves can be excited by a low energy electron beam. Such waves propagate at moderately oblique wave normal angles (~70). The potential effects of beam-driven ECH waves on electron dynamics in Earth's plasma sheet is not known. Using two-dimensional Darwin particle-in-cell simulations with initial electron distributions that represent typical plasma conditions in the plasma sheet, we explore the excitation and saturation of such beam-driven ECH waves. Both ECH and electron acoustic waves are excited in the simulation and propagate at oblique wave normal angles. Compared with the electron acoustic waves, ECH waves grow much faster and have more intense saturation amplitudes. Cold, stationary electrons are first accelerated by ECH waves through cyclotron resonance and then accelerated in the parallel direction by both the ECH and electron acoustic waves through Landau resonance. Beam electrons, on the other hand, are decelerated in the parallel direction and scattered to larger pitch angles. The relaxation of the electron beam and the continuous heating of the cold electrons contribute to ECH wave saturation and suppress the excitation of electron acoustic waves. When the ratio of plasma to electron cyclotron frequency wpe/wce increases, the ECH wave amplitude increases while the electron acoustic wave amplitude decreases. Our work reveals the importance of ECH and electron acoustic waves in reshaping sub-thermal electron distributions and improves our understanding on the potential effects of wave-particle interactions in trapping ionospheric electron outflows and forming anisotropic (field-aligned) electron distributions in the plasma sheet.

Published

2024

20. Equatorial source of oblique electromagnetic ion cyclotron waves: peculiarities in the ion distribution function

Author

Tonoian, David S., Zhang, Xiao-Jia, Artemyev, Anton, and An, Xin

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Electromagnetic ion cyclotron (EMIC) waves are important for Earth's inner magnetosphere as they can effectively drive relativistic electron losses to the atmosphere and energetic (ring current) ion scattering and isotropization. EMIC waves are generated by transversely anisotropic ion populations around the equatorial source region, and for typical magnetospheric conditions this almost always produces field-aligned waves. For many specific occasions, however, oblique EMIC waves are observed, and such obliquity has been commonly attributed to the wave off-equatorial propagation in curved dipole magnetic fields. In this study, we report that very oblique EMIC waves can be directly generated at the equatorial source region. Using THEMIS spacecraft observations at the dawn flank, we show that such oblique wave generation is possible in the presence of a field-aligned thermal ion population, likely of ionospheric origin, which can reduce Landau damping of oblique EMIC waves and cyclotron generation of field-aligned waves. This generation mechanism underlines the importance of magnetosphere-ionosphere coupling processes in controlling wave characteristics in the inner magnetosphere.

Published

2024

21. Nonlinear Resonant Interactions of Radiation Belt Electrons with Intense Whistler-Mode Waves

Author

Artemyev, A. V., Mourenas, D., Zhang, X.-J., Agapitov, O., Neishtadt, A. I., Vainchtein, D. L., Vasiliev, A. A., Zhang, X., Ma, Q., Bortnik, J., and Krasnoselskikh, V. V.

Published

2025

22. Compound electron acceleration at planetary foreshocks

Author

Xiaofei Shi, Anton Artemyev, Vassilis Angelopoulos, Terry Liu, and Lynn B. Wilson III

Subjects

Science

Abstract

Abstract Shock waves, the interface of supersonic and subsonic plasma flows, are the primary region for charged particle acceleration in multiple space plasma systems, including Earth’s bow shock, which is readily accessible for in-situ measurements. Spacecraft frequently observe relativistic electron populations within this region, characterized by energy levels surpassing those of solar wind electrons by a factor of 10,000 or more. However, mechanisms of such strong acceleration remain elusive. Here we use observations of electrons with energies up to 200 kiloelectron volts and a data-constrained model to reproduce the observed power-law electron spectrum and demonstrate that the acceleration by more than 4 orders of magnitude is a compound process including a complex, multi-step interaction between more commonly known mechanisms and resonant scattering by several distinct plasma wave modes. The proposed model of electron acceleration addresses a decades-long issue of the generation of energetic (and relativistic) electrons at planetary plasma shocks. This work may further guide numerical simulations of even more effective electron acceleration in astrophysical shocks.

Published

2025

23. Triggering the magnetopause reconnection by solar wind discontinuities

Author

Lukin, Alexander, Guo, Zhifang, Lin, Yu, Panov, Evgeny, Artemyev, Anton, Zhang, Xiaojia, and Petrukovich, Anatoli

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Magnetic reconnection is one of the most universal processes in space plasma that is responsible for charged particle acceleration, mixing and heating of plasma populations. In this paper we consider a triggering process of reconnection that is driven by interaction of two discontinuities: solar wind rotational discontinuity and tangential discontinuity at the Earth's magnetospheric boundary, magnetopause. Combining the multispacecraft measurements and global hybrid simulations, we show that solar wind discontinuities may drive the magnetopause reconnection and cause the mixing of the solar wind and magnetosphere plasmas around the magnetopause, well downstream of the solar wind flow. Since large-amplitude discontinuities are frequently observed in the solar wind and predicted for various stellar winds, our results of reconnection driven by the discontinuity-discontinuity interaction may have a broad application beyond the magnetosphere.

Published

2023

24. Properties of Intense Electromagnetic Ion Cyclotron Waves: Implications for Quasi-linear, Nonlinear, and Nonresonant Wave-Particle Interactions

Author

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

Subjects

Physics - Plasma Physics, Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

Resonant interactions between relativistic electrons and electromagnetic ion cyclotron (EMIC) waves provide an effective loss mechanism for this important electron population in the outer radiation belt. The diffusive regime of electron scattering and loss has been well incorporated into radiation belt models within the framework of the quasi-linear diffusion theory, whereas the nonlinear regime has been mostly studied with test particle simulations. There is also a less investigated, nonresonant regime of electron scattering by EMIC waves. All three regimes should be present, depending on the EMIC waves and ambient plasma properties, but the occurrence rates of these regimes have not been previously quantified. This study provides a statistical investigation of the most important EMIC wave-packet characteristics for the diffusive, nonlinear, and nonresonant regimes of electron scattering. We utilize 3 years of Van Allen Probe observations to derive distributions of wave amplitudes, wave-packet sizes, and rates of frequency variations within individual wave-packets. We demonstrate that EMIC waves typically propagate as wave-packets with $\sim 10$ wave periods each, and that $\sim 3-10$\% of such wave-packets can reach the regime of nonlinear resonant interaction with 2 to 6 MeV electrons. We show that EMIC frequency variations within wave-packets reach $50-100$\% of the center frequency, corresponding to a significant high-frequency tail in their wave power spectrum. We explore the consequences of these wave-packet characteristics for high and low energy electron precipitation by H-band EMIC waves and for the relative importance of quasi-linear and nonlinear regimes of wave-particle interactions.

Published

2023

25. Relativistic electron precipitation events driven by solar wind impact on the Earth's magnetosphere

Author

Roosnovo, Alexandra, Artemyev, Anton V., Zhang, Xiao-Jia, Angelopoulos, Vassilis, Ma, Qianli, Grimmich, Niklas, Plaschke, Ferdinand, Fischer, David, and Werner, Magnes

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Certain forms of solar wind transients contain significant enhancements of dynamic pressure and may effectively drive magnetosphere dynamics, including substorms and storms. An integral element of such driving is the generation of a wide range of electromagnetic waves within the inner magnetosphere, either by compressionally heated plasma or by substorm plasma sheet injections. Consequently, solar wind transient impacts are traditionally associated with energetic electron scattering and losses into the atmosphere by electromagnetic waves. In this study, we show the first direct measurements of two such transient-driven precipitation events as measured by the low-altitude Electron Losses and Fields Investigation (ELFIN) CubeSats. The first event demonstrates storm-time generated electromagnetic ion cyclotron waves efficiently precipitating relativistic electrons from >300 keV to 2 MeV at the duskside. The second event demonstrates whistler-mode waves leading to scattering of electrons from 50 keV to 700 keV on the dawnside. These observations confirm the importance of solar wind transients in driving energetic electron losses and subsequent dynamics in the ionosphere.

Published

2023

26. Ion kinetics of plasma interchange reconnection in the lower solar corona

Author

Krasnoselskikh, Vladimir, Zaslavsky, Arnaud, Artemyev, Anton, Froment, Clara, de Wit, Thierry Dudok, Raouafi, Nour E., Agapitov, Oleksiy V., Bale, Stuart D., and Verniero, Jaye L.

Subjects

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

Abstract

The exploration of the inner heliosphere by Parker Solar Probe has revealed a highly structured solar wind with ubiquitous deflections from the Parker spiral, known as switchbacks. Interchange reconnection (IR) may play an important role in generating these switchbacks by forming unstable particle distributions that generate wave activity that in turn may evolve to such structures. IR occurs in very low beta plasmas and in the presence of strong guiding fields. Although IR is unlikely to release enough energy to provide an important contribution to the heating and acceleration of the solar wind, it affects the way the solar wind is connected to its sources, connecting open field lines to regions of closed fields. This "switching on" provides a mechanism by which plasma near coronal hole boundaries can mix with that trapped inside the closed loops. This mixing can lead to a new energy balance. It may significantly change the characteristics of the solar wind because this plasma is already pre-heated and can potentially have quite different density and particle distributions. It not only replenishes the solar wind, but also affects the electric field, which in turn affects the energy balance. This interpenetration is manifested by the formation of a bimodal ion distribution, with a core and a beam-like population. Such distributions are indeed frequently observed by the Parker Solar Probe. Here we provide a first step towards assessing the role of such processes in accelerating and heating the solar wind., Comment: Accepted in Parker Solar Probe Focus Issue (ApJ)

Published

2023

27. Ores and Metallurgical Slag from the Settlements of the Elenovka and Ushkatta Archaeological Microdistricts in the Orenburg Oblast

Author

Fomichev, A. V., Ankushev, M. N., Artemyev, D. A., and Blinov, I. A.

Published

2024

28. State of Zoobenthic Communities in Lakes Bannoe (Solovetsky Archipelago) and Kholmovskoe (Northern Dvina River Basin)

Author

Novoselov, A. P., Artemyev, S. N., Pryanichnikova, E. G., Dvoryankin, G. A., Matveev, N. Yu., and Imant, E. N.

Published

2024

29. mKate2-K67R/R197H—Extra-Bright Red Fluorescent Biomarker of New Generation. X-Ray Structure and Molecular Dynamic Properties

Author

Goryacheva, E. A., Rossokhin, A. V., Ruchkin, D. A., Bogdanov, A. M., Artemyev, I. V., Pletneva, N. V., and Plenev, V. Z.

Published

2024

30. Hybrid Layers of Laterally Oriented Plasmon Silver Nanoplates and Luminescent Quantum Dots with Resonance Energy Transfer

Author

Muravsky, D. I., Malakhovsky, P. O., Ramanenka, A. A., and Artemyev, M. V.

Published

2024

31. Thin current sheets in the magnetotail at lunar distances: statistics of ARTEMIS observations

Author

Kamaletdinov, S. R., Artemyev, A. V., Runov, A., and Angelopoulos, V.

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

The magnetotail current sheet's spatial configuration and stability control the onset of magnetic reconnection - the driving process for magnetospheric substorms. The near-Earth current sheet has been thoroughly investigated by numerous missions, whereas the midtail current sheet has not been adequately explored. This is especially the case for the long-term variation of its configuration in response to the solar wind. We present a statistical analysis of 1261 magnetotail current sheet crossings by the Acceleration, Reconnection, Turbulence and Electrodynamics of Moon's Interaction with the Sun (ARTEMIS) mission orbiting the moon (X~-60 RE), collected during the entirety of Solar Cycle 24. We demonstrate that the magnetotail current sheet typically remains extremely thin, with a characteristic thickness comparable to the thermal ion gyroradius, even at such large distances from Earth's dipole. We also find that a substantial fraction (~one quarter) of the observed current sheets have a partially force-free magnetic field configuration, with a negligible contribution of the thermal pressure and a significant contribution of the magnetic field shear component to the pressure balance. Further, we quantify the impact of the changing solar wind driving conditions on the properties of the midtail around the lunar orbit. During active solar wind driving conditions, we observe an increase in the occurrence rate of thin current sheets, whereas quiet solar wind driving conditions seem to favor the formation of partially force-free current sheets.

Published

2023

32. Electron Precipitation Observed by ELFIN Using Proton Precipitation as a Proxy for Electromagnetic Ion Cyclotron (EMIC) Waves

Author

Capannolo, Luisa, Li, Wen, Ma, Qianli, Qin, Murong, Shen, Xiao-Chen, Angelopoulos, Vassilis, Artemyev, Anton, Zhang, Xiao-Jia, and Hanzelka, Mirek

Subjects

Physics - Space Physics

Abstract

Electromagnetic Ion Cyclotron (EMIC) waves can drive radiation belt depletion and Low-Earth Orbit (LEO) satellites can detect the resulting electron and proton precipitation. The ELFIN (Electron Losses and Fields InvestigatioN) CubeSats provide an excellent opportunity to study the properties of EMIC-driven electron precipitation with much higher energy and pitch-angle resolution than previously allowed. We collect EMIC-driven electron precipitation events from ELFIN observations and use POES (Polar Orbiting Environmental Satellites) to search for 10s-100s keV proton precipitation nearby as a proxy of EMIC wave activity. Electron precipitation mainly occurs on localized radial scales (0.3 L), over 15-24 MLT and 5-8 L shells, stronger at MeV energies and weaker down to 100-200 keV. Additionally, the observed loss cone pitch-angle distribution agrees with quasilinear predictions at >250 keV (more filled loss cone with increasing energy), while additional mechanisms are needed to explain the observed low-energy precipitation., Comment: This manuscript has been accepted by Geophysical Research Letters in June 2023, currently pending publication. The version here is the accepted version

Published

2023

33. Electron resonant interaction with whistler-mode waves around the Earth's bow shock II: the mapping technique

Author

Tonoian, David S., Shi, Xiaofei, Artemyev, Anton V., Zhang, Xiao-Jia, and Angelopoulos, Vassilis

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Electron resonant scattering by high-frequency electromagnetic whistler-mode waves has been proposed as a mechanism for solar wind electron scattering and pre-acceleration to energies that enable them to participate in shock drift acceleration around the Earth's bow shock. However, observed whistler-mode waves are often sufficiently intense to resonate with electrons nonlinearly, which prohibits the application of quasi-linear diffusion theory. This is the second of two accompanying papers devoted to developing a new theoretical approach for quantifying the electron distribution evolution subject to multiple resonant interactions with intense whistler-mode wave-packets. In the first paper, we described a probabilistic approach, applicable to systems with short wave-packets. For such systems, nonlinear resonant effects can be treated by diffusion theory, but with diffusion rates different from those of quasi-linear diffusion. In this paper we generalize this approach by merging it with a mapping technique. This technique can be used to model the electron distribution evolution in the presence of significantly non-diffusive resonant scattering by intense long wave-packets. We verify our technique by comparing its predictions with results from a numerical integration approach.

Published

2023

34. Electron resonant interaction with whistler-mode waves around the Earth's bow shock I: the probabilistic approach

Author

Shi, Xiaofei, Tonoian, David S., Artemyev, Anton V., Zhang, Xiao-Jia, and Angelopoulos, Vassilis

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Adiabatic heating of solar wind electrons at the Earth's bow shock and its foreshock region produces transversely anisotropic hot electrons that, in turn, generate intense high-frequency whistler-mode waves. These waves are often detected by spacecraft as narrow-band, electromagnetic emissions in the frequency range of [0.1,0.5] of the local electron gyrofrequency. Resonant interactions between these waves and electrons may cause electron acceleration and pitch-angle scattering, which can be important for creating the electron population that seeds shock drift acceleration. The high intensity and coherence of the observed whistler-mode waves prohibit the use of quasi-linear theory to describe their interaction with electrons. In this paper, we aim to develop a new theoretical approach to describe this interaction, that incorporates nonlinear resonant interactions, gradients of the background density and magnetic field, and the fine structure of the waveforms that usually consist of short, intense wave-packet trains. This is the first of two accompanying papers. It outlines a probabilistic approach to describe the wave-particle interaction. We demonstrate how the wave-packet size affects electron nonlinear resonance at the bow shock and foreshock regions, and how to evaluate electron distribution dynamics in such a system that is frequented by short, intense whistler-mode wave-packets. In the second paper, this probabilistic approach is merged with a mapping technique, which allows us to model systems containing short and long wave-packets.

Published

2023

35. Nonlinear Landau resonant interaction between whistler waves and electrons: Excitation of electron acoustic waves

Author

Ma, Donglai, An, Xin, Artemyev, Anton, Bortnik, Jacob, Angelopoulos, Vassilis, and Zhang, Xiao-Jia

Subjects

Physics - Plasma Physics, Physics - Space Physics

Abstract

Electron acoustic waves (EAWs), as well as electron-acoustic solitary structures, play a crucial role in thermalization and acceleration of electron populations in Earth's magnetosphere. These waves are often observed in association with whistler-mode waves, but the detailed mechanism of EAW and whistler wave coupling is not yet revealed. We investigate the excitation mechanism of EAWs and their potential relation to whistler waves using particle-in-cell simulations. Whistler waves are first excited by electrons with a temperature anisotropy perpendicular to the background magnetic field. Electrons trapped by these whistler waves through nonlinear Landau resonance form localized field-aligned beams, which subsequently excite EAWs. By comparing the growth rate of EAWs and the phase mixing rate of trapped electron beams, we obtain the critical condition for EAW excitation, which is consistent with our simulation results across a wide region in parameter space. These results are expected to be useful in the interpretation of concurrent observations of whistler-mode waves and nonlinear solitary structures, and may also have important implications for investigation of cross-scale energy transfer in the near-Earth space environment.

Published

2023

36. Embedded coherent structures from MHD to sub-ion scales in turbulent solar wind at 0.17 au

Author

Vinogradov, Alexander, Alexandrova, Olga, Démoulin, Pascal, Artemyev, Anton, Maksimovic, Milan, Mangeney, André, Vasiliev, Alexei, Petrukovich, Anatoly, and Bale, Stuart

Subjects

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

Abstract

We study intermittent coherent structures in solar wind magnetic turbulence from MHD to kinetic plasma scales using Parker Solar Probe data during its first perihelion (at 0.17 au), when the satellite was in the Alfv\'enic slow wind of 340 km/s. The coherent structures are energetic events localized in time and covering wide range of scales. We detect them using Morlet wavelets. For the first time, we apply a multi-scale analyses in physical space to study these structures. At MHD scales within the inertial range, times scales $\tau \in (1, 10^{2} )$ s, we find (i) current sheets including switchback boundaries and (ii) Alfv\'en vortices. Within these events, there are embedded structures at smaller scales: typically Alfv\'en vortices at ion scales, $\tau \in (0.08, 1)$ s, and a compressible vortices at sub-ion scales, $\tau \in (8,80)$ ms. The number of coherent structures grows toward smaller scales: we observe about $\sim 200$ events during 5 h time interval at MHD scales, $\sim 10^{3}$ events ai ion scales and $\sim 10^{4}$ events at sub-ion scales. In general, there are multiple structures of ion and sub-ion scales embedded within one MHD structure. There are also examples of ion and sub-ion scales structures outside of MHD structures. To quantify the relative importance of different type of structures, we do a statistical comparison of the observed structures with the expectations of models of the current sheets and vortices. This comparison is based on amplitude anisotropy of magnetic fluctuations within the structures. The results show the dominance of Alfv\'en vortices at all scales in contrast to the widespread view of dominance of current sheets. This means that Alfv\'en vortices are important building blocs of solar wind turbulence., Comment: Revised version of the article, accepted for publication in Astrophysical Journal, 30 pages, 15 figures

Published

2023

37. Nonresonant scattering of energetic electrons by electromagnetic ion cyclotron waves: spacecraft observations and theoretical framework

Author

An, Xin, Artemyev, Anton, Angelopoulos, Vassilis, Zhang, Xiao-Jia, Mourenas, Didier, Bortnik, Jacob, and Shi, Xiaofei

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Electromagnetic ion cyclotron (EMIC) waves lead to rapid scattering of relativistic electrons in Earth's radiation belts, due to their large amplitudes relative to other waves that interact with electrons of this energy range. A central feature of electron precipitation driven by EMIC waves is deeply elusive. That is, moderate precipitating fluxes at energies below the minimum resonance energy of EMIC waves occur concurrently with strong precipitating fluxes at resonance energies in low-altitude spacecraft observations. This paper expands on a previously reported solution to this problem: nonresonant scattering due to wave packets. The quasi-linear diffusion model is generalized to incorporate nonresonant scattering by a generic wave shape. The diffusion rate decays exponentially away from the resonance, where shorter packets lower decay rates and thus widen the energy range of significant scattering. Using realistic EMIC wave packets from $\delta f$ particle-in-cell simulations, test particle simulations are performed to demonstrate that intense, short packets extend the energy of significant scattering well below the minimum resonance energy, consistent with our theoretical prediction. Finally, the calculated precipitating-to-trapped flux ratio of relativistic electrons is compared to ELFIN observations, and the wave power spectra is inferred based on the measured flux ratio. We demonstrate that even with a narrow wave spectrum, short EMIC wave packets can provide moderately intense precipitating fluxes well below the minimum resonance energy., Comment: 32 pages, 9 figures

Published

2023

38. HEMATITE-CARBONATE ROCKS OF THE YUBILEYNOE MASSIVE SULFIDE DEPOSIT (SOUTH URALS): EVIDENCE OF REPLACEMENT OF SULFIDE CLASTS AND HYALOCLASTS

Author

A.S. Tseluyko, N.R. Ayupova, D.A. Artemyev, M.A. Rassomakhin, and V.A. Kotlyarov

Subjects

hematite-carbonate gossanites, submarine hypergenesis, halmyrolyisis, hyaloclasts, sulfides, tellurides, la-icp-ms, yubileynoe massive sulfide deposit, Mineralogy, QE351-399.2

Abstract

The article considers textural and structural features of hematite-carbonate rocks associated with carbonate-sulfide clastic ores of the Yubileynoe massive sulfide deposit, South Urals. Some hematitecarbonate rocks exhibit signatures of the replacement of sulfide clasts and hyaloclasts by hematite-carbonate material, classified as carbonate analogs of gossanites. The hematite-carbonate aggregates after sulfide clasts are characterized by inherited reniform-colloform, radial and crystalline-granular structures, as well as the inclusions of relict sulfides and tellurides. The hematite-carbonate aggregates after sulfide clasts contain the elevated concentrations of chalcophile (Cu, Zn, Pb, As, Sb, Bi, Te) and lithophile (Ti, Zr, V, W) trace elements. The hematite-carbonate clasts after hyaloclasts contain aggregates with globular structure and syneresis cracks and contain relics of chlorite. The matrix of hematite-carbonate rocks consists of calcite with inclusions and aggregates of dolomite, chlorite, quartz and apatite. Late sulfide mineralization (pyrite metacrystals, aggregates and veins of chalcopyrite and sphalerite) is characteristic of both hematite-carbonate rocks after sulfide clasts and hyaloclasts.

Published

2024

39. Analytical study of metal from the Petrovka Culture of Northern Kazakhstan

Author

Kuzminykh Sergey V., Degtyareva Anna D., Artemyev Dmitry A., Blinov Ivan A., and Orlovskaya Lyubov B.

Subjects

archaeology, bronze age, northern kazakhstan, petrovka culture, composition of copper and bronze, metallurgical groups, trade and exchange relations, Archaeology, CC1-960

Abstract

The results of spectral, mass spectrometric and energy-dispersive scanning electron microscopy analyzes of non-ferrous metal from the Petrovka culture of the XIX–XVIII centuries BC in Northern Kazakhstan are presented. The metal was mainly analyzed by spectral analysis in the 70s–80s of the XX century in the Laboratory of natural science methods of the Institute of Archaeology of the Russian Academy of Sciences. Since the collection is in the funds of the North Kazakhstan Museum of Regional Studies, sampling for modern types of analysis is excluded. The main purpose of the study is to identify geochemical and metallurgical groups with the possible identification of raw material sources and the main vectors of historical and metallurgical relations. Analysis of the main components of the chemical composition of element-impurities of copper and bronze artifacts proved the conclusion that more than 70% of the objects can be associated with local North Kazakhstan sources connected with copper-skarn/porphyry deposits of the Kokshetau anticlinorium. At the same time, the possible share of Ural metal in the collection could reach up to 30% of the studied inventory, which confirms the intensity of the trade exchange of metallurgical products between the Ural and Kazakhstan centers of metal production.

Published

2024

40. Chemistry of tin bronzes and possible sources of tin in the Urals and Kazakhstan in the Late Bronze Age

Author

Artemyev D.A., Degtyareva A.D., Kuzminykh S.V., Orlovskaya L.B., Alaeva I.P., and Vinogradov N.B.

Subjects

late bronze age, urals, kazakhstan, tin bronze, tin, trace elements, tin deposits, Archaeology, CC1-960

Abstract

The article discusses geochemical groups identified according to the results of the LA-ISP-MS analysis of tin bronzes of the Ural-Kazakhstan region of the Late Bronze Age. Based on the statistical analysis of 13 impurity elements of 74 bronze and tin-containing copper products from the sites of the 2nd — early 1st mil BC in the Southern Trans-Urals and Northern Kazakhstan, seven chemically contrasting groups have been identified, which mark various types of tin sources. A significant part of the metal reflects the polymetallic nature of tin deposits, which are probably associated with the structures of Northern and Central Kazakhstan, where tin was mined together with copper ores. The second part of the sample — without a clear correlation of tin with other metals — reflects the cassiterite type of ores. It clearly shows the correlation As-Co-Ni±(Sb, Fe, Au), which is characteristic of the copper deposits of the Urals, indicating the alloying of the Ural copper ores with cassiterite master alloys. Data on tin metallogeny, ore chemistry, types of deposits, and known ancient mines of Northern, Central and Eastern Kazakhstan, which could have been sources of raw materials in the metallurgy of the Late Bronze Age, are presented. The main tin-bearing structures of Kazakhstan are the Kokshetau block in the north, the Kalba-Narym zone in the east, and the Ulytau, Bulattau, Atasu, and Sarysu-Teniz structures in Central Kazakhstan. Greisen, quartz-vein and pegmatite types of primary tin deposits, accompanied by placers, are known here. The ores at the deposits are represented both by pure cassiterite (in association with quartz, wolframite, tourmaline, etc.) and by association with sulphides (chalcopyrite, pyrite, arsenopyrite, galena, bismuthine, etc.) and copper oxide-carbonate ores.

Published

2024

41. Real-time laser speckle contrast imaging for intraoperative neurovascular blood flow assessment: animal experimental study

Author

Konovalov, Anton, Grebenev, Fyodor, Stavtsev, Dmitry, Kozlov, Igor, Gadjiagaev, Vadim, Piavchenko, Gennadii, Telyshev, Dmitry, Gerasimenko, Alexander Yu., Meglinski, Igor, Zalogin, Savely, Artemyev, Anton, Golodnev, Grigorii, Shumeiko, Tatiana, and Eliava, Shalva

Published

2024

42. Single-Stage 3D Geometry-Preserving Depth Estimation Model Training on Dataset Mixtures with Uncalibrated Stereo Data

Author

Patakin, Nikolay, Romanov, Mikhail, Vorontsova, Anna, Artemyev, Mikhail, and Konushin, Anton

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Nowadays, robotics, AR, and 3D modeling applications attract considerable attention to single-view depth estimation (SVDE) as it allows estimating scene geometry from a single RGB image. Recent works have demonstrated that the accuracy of an SVDE method hugely depends on the diversity and volume of the training data. However, RGB-D datasets obtained via depth capturing or 3D reconstruction are typically small, synthetic datasets are not photorealistic enough, and all these datasets lack diversity. The large-scale and diverse data can be sourced from stereo images or stereo videos from the web. Typically being uncalibrated, stereo data provides disparities up to unknown shift (geometrically incomplete data), so stereo-trained SVDE methods cannot recover 3D geometry. It was recently shown that the distorted point clouds obtained with a stereo-trained SVDE method can be corrected with additional point cloud modules (PCM) separately trained on the geometrically complete data. On the contrary, we propose GP$^{2}$, General-Purpose and Geometry-Preserving training scheme, and show that conventional SVDE models can learn correct shifts themselves without any post-processing, benefiting from using stereo data even in the geometry-preserving setting. Through experiments on different dataset mixtures, we prove that GP$^{2}$-trained models outperform methods relying on PCM in both accuracy and speed, and report the state-of-the-art results in the general-purpose geometry-preserving SVDE. Moreover, we show that SVDE models can learn to predict geometrically correct depth even when geometrically complete data comprises the minor part of the training set.

Published

2023

43. Statistical Characteristics of the Electron Isotropy Boundary

Author

Wilkins, Colin, Angelopoulos, Vassilis, Runov, Andrei, Artemyev, Anton, Zhang, Xiao-Jia, Liu, Jiang, and Tsai, Ethan

Subjects

Physics - Space Physics, Physics - Atmospheric and Oceanic Physics, Physics - Plasma Physics

Abstract

Utilizing observations from the ELFIN satellites, we present a statistical study of $\sim$2000 events in 2019-2020 characterizing the occurrence in magnetic local time (MLT) and latitude of $\geq$50 keV electron isotropy boundaries (IBs) at Earth, and the dependence of associated precipitation on geomagnetic activity. The isotropy boundary for an electron of a given energy is the magnetic latitude poleward of which persistent isotropized pitch-angle distributions ($J_{prec}/J_{perp}\sim 1$) are first observed to occur, interpreted as resulting from magnetic field-line curvature scattering (FLCS) in the equatorial magnetosphere. We find that energetic electron IBs can be well-recognized on the nightside from dusk until dawn, under all geomagnetic activity conditions, with a peak occurrence rate of almost 90% near $\sim$22 hours in MLT, remaining above 80% from 21 to 01 MLT. The IBs span a wide range of IGRF magnetic latitudes from $60^\circ$-$74^\circ$, with a maximum occurrence between $66^\circ$-$71^\circ$ (L of 6-8), shifting to lower latitudes and pre-midnight local times with activity. The precipitating energy flux of $\geq$50 keV electrons averaged over the IB-associated latitudes varies over four orders of magnitude, up to $\sim$1 erg/cm$^2$-s, and often includes electron energies exceeding 1 MeV. The local time distribution of IB-associated energies and precipitating fluxes also exhibit peak values near midnight for low activity, shifting toward pre-midnight for elevated activity. The percentage of the total energy deposited over the high-latitude regions ($55^\circ$ to $80^\circ$; or IGRF $L\gtrsim 3$) attributed to IBs is 10-20%, on average, or about 10 MW of total atmospheric power input, but at times can be up to $\sim$100% of the total $\geq$50 keV electron energy deposition over the entire sub-auroral and auroral zone region, exceeding 1 GW in atmospheric power input.

Published

2023

44. K-shell ionization of heavy hydrogen-like ions

Author

Novak, O., Kholodov, R., Surzhykov, A., Artemyev, A. N., and Stöhlker, Th.

Subjects

Physics - Atomic Physics, High Energy Physics - Phenomenology

Abstract

A theoretical study of the K-shell ionization of hydrogen-like ions, colliding with bare nuclei, is performed within the framework of the time-dependent Dirac equation. Special emphasis is placed on the ionization probability that is investigated as a function of impact parameter, collision energy and nuclear charge. To evaluate this probability in a wide range of collisional parameters we propose a simple analytical expression for the transition amplitude. This expression contains three fitting parameters that are determined from the numerical calculations, based on the adiabatic approximation. In contrast to previous studies, our analytical expression for the transition amplitude and ionization probability accounts for the full multipole expansion of the two-center potential and allows accurate description of nonsymmetric collisions of nuclei with different atomic numbers, $Z_1 \neq Z_2$. The calculations performed for both symmetric and asymmetric collisions indicate that the ionization probability is reduced when the difference between the atomic numbers of ions increases., Comment: 8 pages, 6 figures

Published

2023

45. Ionization in a laser assisted ion-ion collision

Author

Novak, O., Kholodov, R., Artemyev, A. N., Surzhykov, A., and Stoehlker, Th.

Subjects

Physics - Atomic Physics, High Energy Physics - Phenomenology

Abstract

The ionization of a hydrogen-like heavy ion by impact of a charged projectile under simultaneous irradiation by a short laser pulse is investigated within the non-perturbative approach, based on numerical solutions of the time-dependent Dirac equation. Special emphasis is placed on the question of whether the laser- and impact-ionization channels interfere with each other, and how this intereference affects the ionization probability. To answer this question we performed detailed calculations for the laser-assisted collisions between hydrogen-like $Pb^{81+}$ and alpha particles. The results of the calculations clearly indicate that for the experimentally relevant set of (collision and laser) parameters, the interference contribution can reach 10% and can be easily controlled by varying the laser frequency., Comment: 9 pages, 10 figures

Published

2023

46. 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

47. Inhomogeneity Ratio for Nearly Field‐Aligned Electrons Interacting With Whistler‐Mode Waves

Author

Longzhi Gan, Wen Li, Jay M. Albert, Miroslav Hanzelka, Qianli Ma, and Anton Artemyev

Subjects

chorus, nonlinear, precipitation, inhomogeneity, anomalous trapping, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Nonlinear interactions between electrons and whistler‐mode chorus waves play an important role in driving electron precipitation in Earth's radiation belts. In this letter, we employ the second fundamental model of the Hamiltonian approach to derive the inhomogeneity ratio, assessing nonlinear resonant interactions between nearly field‐aligned electrons and parallel propagating chorus waves. We perform test particle simulations by launching electrons from a high latitude to the equator, encountering counter‐streaming chorus waves. Our simulations reveal that anomalous scattering, encompassing anomalous trapping and positive bunching, extends the resonant location to the downstream of electrons. The comparison with test particle results demonstrates the efficacy of the inhomogeneity ratio in characterizing nonlinear interactions at small pitch angles. We emphasize the importance of applying this ratio specifically for small pitch angle electrons, as the previously provided inhomogeneity ratio significantly underestimates the impact of nonlinear interactions on electron precipitation.

Published

2025

48. Particle-In-Cell Simulations of Sunward and Anti-sunward Whistler Waves in the Solar Wind

Author

Kuzichev, Ilya V., Vasko, Ivan Y., Artemyev, Anton V., Bale, Stuart D., and Mozer, Forrest S.

Subjects

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

Abstract

Spacecraft observations showed that electron heat conduction in the solar wind is probably regulated by whistler waves, whose origin and efficiency in electron heat flux suppression is actively investigated. In this paper, we present Particle-In-Cell simulations of a combined whistler heat flux and temperature anisotropy instability that can operate in the solar wind. The simulations are performed in a uniform plasma and initialized with core and halo electron populations typical of the solar wind. We demonstrate that the instability produces whistler waves propagating both along (anti-sunward) and opposite (sunward) to the electron heat flux. The saturated amplitudes of both sunward and anti-sunward whistler waves are strongly correlated with their {\it initial} linear growth rates, $B_{w}/B_0\sim (\gamma/\omega_{ce})^{\nu}$, where for typical electron betas we have $0.6\lesssim \nu\lesssim 0.9$. The correlations of whistler wave amplitudes and spectral widths with plasma parameters (electron beta and temperature anisotropy) revealed in the simulations are consistent with those observed in the solar wind. The efficiency of electron heat flux suppression is positively correlated with the saturated amplitude of sunward whistler waves. The electron heat flux can be suppressed by 10--60% provided that the saturated amplitude of sunward whistler waves exceeds about 1% of background magnetic field. Other experimental applications of the presented results are discussed.

Published

2023

49. Kinetic equilibrium of two-dimensional force-free current sheets

Author

An, Xin, Artemyev, Anton, Angelopoulos, Vassilis, Runov, Andrei, and Kamaletdinov, Sergey

Subjects

Physics - Plasma Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Force-free current sheets are local plasma structures with field-aligned electric currents and approximately uniform plasma pressures. Such structures, widely found throughout the heliosphere, are sites for plasma instabilities and magnetic reconnection, the growth rate of which is controlled by the structure's current sheet configuration. Despite the fact that many kinetic equilibrium models have been developed for one-dimensional (1D) force-free current sheets, their two-dimensional (2D) counterparts, which have a magnetic field component normal to the current sheets, have not received sufficient attention to date. Here, using particle-in-cell simulations, we search for such 2D force-free current sheets through relaxation from an initial, magnetohydrodynamic equilibrium. Kinetic equilibria are established toward the end of our simulations, thus demonstrating the existence of kinetic force-free current sheets. Although the system currents in the late equilibrium state remain field aligned as in the initial configuration, the velocity distribution functions of both ions and electrons systematically evolve from their initial drifting Maxwellians to their final time-stationary Vlasov state. The existence of 2D force-free current sheets at kinetic equilibrium necessitates future work in discovering additional integrals of motion of the system, constructing the kinetic distribution functions, and eventually investigating their stability properties., Comment: Published in ApJ, 20 pages with 14 figures

Published

2023

50. Force-free current sheets in the Jovian magnetodisk: the key role of electron field-aligned anisotropy

Author

Artemyev, A. V., Ma, Q., Ebert, R. W., Zhang, X. -J., and Allegrini, F.

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Current sheets are an essential element of the planetary magnetotails, where strong plasma currents self-consistently support magnetic field gradients. The current sheet configuration is determined by plasma populations that contribute to the current density. The most commonly investigated configuration is supported by diamagnetic cross-field currents of hot ions, typical for the magnetospheres of magnetized planets. In this study, we examine a new type of the current sheet configuration supported by field-aligned currents from electron streams in the Jovian magnetodisk. Such bi-directional streams increase the electron thermal anisotropy close to the fire-hose instability threshold and lead to strong magnetic field shear. The current sheet configuration supported by electron streams is nearly force-free, with B=const across the sheet. Using Juno plasma and magnetic field measurements, we investigate the internal structure of such current sheets and discuss possible mechanisms for their formation.

Published

2023