Your search keyword '"Tarvus, V."' showing total 16 results

1. Parametrization of coefficients for sub-grid modeling of pitch-angle diffusion in global magnetospheric hybrid-Vlasov simulations

Author

Dubart, M., primary, Battarbee, M., additional, Ganse, U., additional, Osmane, A., additional, Spanier, F., additional, Suni, J., additional, Cozzani, G., additional, Horaites, K., additional, Papadakis, K., additional, Pfau-Kempf, Y., additional, Tarvus, V., additional, and Palmroth, M., additional

Published

2023

2. Magnetospheric Response to a Pressure Pulse in a Three‐Dimensional Hybrid‐Vlasov Simulation

Author

Horaites, K., primary, Rintamäki, E., additional, Zaitsev, I., additional, Turc, L., additional, Grandin, M., additional, Cozzani, G., additional, Zhou, H., additional, Alho, M., additional, Suni, J., additional, Kebede, F., additional, Gordeev, E., additional, George, H., additional, Battarbee, M., additional, Bussov, M., additional, Dubart, M., additional, Ganse, U., additional, Papadakis, K., additional, Pfau‐Kempf, Y., additional, Tarvus, V., additional, and Palmroth, M., additional

Published

2023

3. Dayside Pc2 Waves Associated With Flux Transfer Events in a 3D Hybrid‐Vlasov Simulation.

Author

Tesema, F., Palmroth, M., Turc, L., Zhou, H., Cozzani, G., Alho, M., Pfau‐Kempf, Y., Horaites, K., Zaitsev, I., Grandin, M., Battarbee, M., Ganse, U., Workayehu, A., Suni, J., Papadakis, K., Dubart, M., and Tarvus, V.

Subjects

MAGNETIC reconnection, GEOMAGNETISM, MAGNETOPAUSE, OCEAN wave power, MAGNETOSPHERE, SOLAR wind

Abstract

Flux transfer events (FTEs) are transient magnetic flux ropes at Earth's dayside magnetopause formed due to magnetic reconnection. As they move across the magnetopause surface, they can generate disturbances in the ultralow frequency (ULF) range, which then propagate into the magnetosphere. This study provides evidence of ULF waves in the Pc2 wave frequency range (>0.1 Hz) caused by FTEs during dayside reconnection using a global 3D hybrid‐Vlasov simulation (Vlasiator). These waves resulted from FTE formation and propagation at the magnetopause are particularly associated with large, rapidly moving FTEs. The wave power is stronger in the morning than afternoon, showing local time asymmetry. In the pre and postnoon equatorial regions, significant poloidal and toroidal components are present alongside the compressional component. The noon sector, with fewer FTEs, has lower wave power and limited magnetospheric propagation. Plain Language Summary: The Earth's magnetosphere is a dynamic region shaped by the interplay between the solar wind and Earth's magnetic field. This interaction occurs at the boundary of the magnetosphere (magnetopause) through a process known as magnetic reconnection, giving rise to Flux Transfer Events (FTEs), which are magnetic structures that carry flux and energy into the magnetosphere. These FTEs form either in sudden bursts, patchy patterns or in a continuous, and relatively stable way making the magnetopause surface dynamic. As the FTEs move along the boundary of the magnetosphere, they create compressed regions and lead to wave generation that can extend into the magnetosphere. The study uses an advanced 3D hybrid‐Vlasov simulation model to analyze waves originated from FTE formation and propagation at the magnetopause. We find that rapidly moving and large FTEs have a significant impact on the magnetopause, leading to the generation of ULF waves with frequency above 0.1 Hz. This shows first direct evidence supporting previous theoretical speculations regarding the ability of FTEs to generate waves near the magnetopause. Key Points: Dayside Pc2 waves (>0.1 Hz) have been detected in a 3D hybrid‐Vlasov simulationThese waves exhibit lower intensity within the magnetosphere at noon, compared to the prenoon and postnoon sectorsPc2 waves observed in the simulation are associated with largest and fast moving flux transfer events initiated by subsolar reconnection [ABSTRACT FROM AUTHOR]

Published

2024

4. Six-dimensional view of Earth’s magnetosphere with the Vlasiator simulation

Author

Turc, L., Palmroth, M., Grandin, M., Horaites, K., Alho, M., Battarbee, M., Bussov, M., Cozzani, G., Dubart, M., Ganse, U., Gordeev, E., Papadakis, K., Pfau-Kempf, Y., Suni, J., Tarvus, V., Tesema, F., Zaitsev, I., and Zhou, H.

Abstract

Vlasiator is a hybrid-Vlasov model designed for global simulations of Earth's magnetosphere. In the hybrid-Vlasov approach, ions are described as velocity distribution functions and electrons are a charge-neutralising fluid. This provides a self-consistent description of ion dynamics in the global magnetospheric context. Vlasiator simulations have been at first confined to two dimensions in ordinary space (2D) and three in velocity space (3V), due to their high computational cost. The recent implementation of adaptive mesh refinement now makes it possible to run 6D (3D-3V) global simulations of Earth's magnetosphere. Here we present an overview of recent results obtained with these new 6D simulations, pertaining to magnetotail dynamics, magnetopause motion, and particle precipitation into the ionosphere. The runs are carried out with a purely southward interplanetary magnetic field, which is conducive to dayside and nightside reconnection. On the dayside, we find that cusp proton precipitation is modulated by flux transfer events formed by magnetopause reconnection. In the magnetotail, the global simulation reveals the interplay between instabilities and reconnection, and their combined role in global magnetotail reconfiguration. We also study the motion of the magnetopause in response to an enhancement in the solar wind dynamic pressure., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published

2023

5. Sub-grid modeling of pitch-angle diffusion for ion-scale waves in hybrid-Vlasov simulations with Cartesian velocity space

Author

Dubart, M., primary, Battarbee, M., additional, Ganse, U., additional, Osmane, A., additional, Spanier, F., additional, Suni, J., additional, Johlander, A., additional, Alho, M., additional, Bussov, M., additional, Cozzani, G., additional, George, H., additional, Grandin, M., additional, Horaites, K., additional, Papadakis, K., additional, Pfau-Kempf, Y., additional, Tarvus, V., additional, Turc, L., additional, Zaitsev, I., additional, Zhou, H., additional, and Palmroth, M., additional

Published

2022

6. Electron Signatures of Reconnection in a Global eVlasiator Simulation

Author

Alho, M., primary, Battarbee, M., additional, Pfau‐Kempf, Y., additional, Khotyaintsev, Yu. V., additional, Nakamura, R., additional, Cozzani, G., additional, Ganse, U., additional, Turc, L., additional, Johlander, A., additional, Horaites, K., additional, Tarvus, V., additional, Zhou, H., additional, Grandin, M., additional, Dubart, M., additional, Papadakis, K., additional, Suni, J., additional, George, H., additional, Bussov, M., additional, and Palmroth, M., additional

Published

2022

7. Electron Signatures of Reconnection in a Global eVlasiator Simulation

Author

Alho, M., Battarbee, M., Pfau-Kempf, Y., Khotyaintsev, Yuri V., Nakamura, R., Cozzani, G., Ganse, U., Turc, L., Johlander, A., Horaites, K., Tarvus, V, Zhou, H., Grandin, M., Dubart, M., Papadakis, K., Suni, J., George, H., Bussov, M., Palmroth, M., Alho, M., Battarbee, M., Pfau-Kempf, Y., Khotyaintsev, Yuri V., Nakamura, R., Cozzani, G., Ganse, U., Turc, L., Johlander, A., Horaites, K., Tarvus, V, Zhou, H., Grandin, M., Dubart, M., Papadakis, K., Suni, J., George, H., Bussov, M., and Palmroth, M.

Abstract

Geospace plasma simulations have progressed toward more realistic descriptions of the solar wind-magnetosphere interaction from magnetohydrodynamic to hybrid ion-kinetic, such as the state-of-the-art Vlasiator model. Despite computational advances, electron scales have been out of reach in a global setting. eVlasiator, a novel Vlasiator submodule, shows for the first time how electromagnetic fields driven by global hybrid-ion kinetics influence electrons, resulting in kinetic signatures. We analyze simulated electron distributions associated with reconnection sites and compare them with Magnetospheric Multiscale (MMS) spacecraft observations. Comparison with MMS shows that key electron features, such as reconnection inflows, heated outflows, flat-top distributions, and bidirectional streaming, are in remarkable agreement. Thus, we show that many reconnection-related features can be reproduced despite strongly truncated electron physics and an ion-scale spatial resolution. Ion-scale dynamics and ion-driven magnetic fields are shown to be significantly responsible for the environment that produces electron dynamics observed by spacecraft in near-Earth plasmas.

Published

2022

8. Estimating Inner Magnetospheric Radial Diffusion Using a Hybrid-Vlasov Simulation

Author

George, H., Osmane, A., Kilpua, E. K. J., Lejosne, S., Turc, L., Grandin, M., Kalliokoski, M. M. H., Hoilijoki, S., Ganse, U., Alho, M., Battarbee, M., Bussov, M., Dubart, M., Johlander, Andreas, Manglayev, T., Papadakis, K., Pfau-Kempf, Y., Suni, J., Tarvus, V., Zhou, H., Palmroth, M., George, H., Osmane, A., Kilpua, E. K. J., Lejosne, S., Turc, L., Grandin, M., Kalliokoski, M. M. H., Hoilijoki, S., Ganse, U., Alho, M., Battarbee, M., Bussov, M., Dubart, M., Johlander, Andreas, Manglayev, T., Papadakis, K., Pfau-Kempf, Y., Suni, J., Tarvus, V., Zhou, H., and Palmroth, M.

Abstract

Radial diffusion coefficients quantify non-adiabatic transport of energetic particles by electromagnetic field fluctuations in planetary radiation belts. Theoretically, radial diffusion occurs for an ensemble of particles that experience irreversible violation of their third adiabatic invariant, which is equivalent to a change in their Roederer L* parameter. Thus, the Roederer L* coordinate is the fundamental quantity from which radial diffusion coefficients can be computed. In this study, we present a methodology to calculate the Lagrangian derivative of L* from global magnetospheric simulations, and test it with an application to Vlasiator, a hybrid-Vlasov model of near-Earth space. We use a Hamiltonian formalism for particles confined to closed drift shells with conserved first and second adiabatic invariants to compute changes in the guiding center drift paths due to electric and magnetic field fluctuations. We investigate the feasibility of this methodology by computing the time derivative of L* for an equatorial ultrarelativistic electron population travelling along four guiding center drift paths in the outer radiation belt during a 5 minute portion of a Vlasiator simulation. Radial diffusion in this simulation is primarily driven by ultralow frequency waves in the Pc3 range (10-45 s period range) that are generated in the foreshock and transmitted through the magnetopause to the outer radiation belt environment. Our results show that an alternative methodology to compute detailed radial diffusion transport is now available and could form the basis for comparison studies between numerical and observational measurements of radial transport in the Earth's radiation belts.

Published

2022

9. Sub-grid modeling of pitch-angle diffusion for ion-scale waves in hybrid-Vlasov simulations with Cartesian velocity space

Author

Dubart, M., Battarbee, M., Ganse, U., Osmane, A., Spanier, F., Suni, J., Johlander, Andreas, Alho, M., Bussov, M., Cozzani, G., George, H., Grandin, M., Horaites, K., Papadakis, K., Pfau-Kempf, Y., Tarvus, V., Turc, L., Zaitsev, I., Zhou, H., Palmroth, M., Dubart, M., Battarbee, M., Ganse, U., Osmane, A., Spanier, F., Suni, J., Johlander, Andreas, Alho, M., Bussov, M., Cozzani, G., George, H., Grandin, M., Horaites, K., Papadakis, K., Pfau-Kempf, Y., Tarvus, V., Turc, L., Zaitsev, I., Zhou, H., and Palmroth, M.

Abstract

Numerical simulations have grown to play a central role in modern sciences over the years. The ever-improving technology of supercomputers has made large and precise models available. However, this accuracy is often limited by the cost of computational resources. Lowering the simulation's spatial resolution in order to conserve resources can lead to key processes being unresolved. We have shown in a previous study how insufficient spatial resolution of the proton cyclotron instability leads to a misrepresentation of ion dynamics in hybrid-Vlasov simulations. This leads to larger than expected temperature anisotropy and loss-cone shaped velocity distribution functions. In this study, we present a sub-grid numerical model to introduce pitch-angle diffusion in a 3D Cartesian velocity space, at a spatial resolution where the relevant wave-particle interactions were previously not correctly resolved. We show that the method is successfully able to isotropize loss-cone shaped velocity distribution functions, and that this method could be applied to simulations in order to save computational resources and still correctly model wave-particle interactions.

Published

2022

10. Estimating Inner Magnetospheric Radial Diffusion Using a Hybrid-Vlasov Simulation

Author

George, H., primary, Osmane, A., additional, Kilpua, E. K. J., additional, Lejosne, S., additional, Turc, L., additional, Grandin, M., additional, Kalliokoski, M. M. H., additional, Hoilijoki, S., additional, Ganse, U., additional, Alho, M., additional, Battarbee, M., additional, Bussov, M., additional, Dubart, M., additional, Johlander, A., additional, Manglayev, T., additional, Papadakis, K., additional, Pfau-Kempf, Y., additional, Suni, J., additional, Tarvus, V., additional, Zhou, H., additional, and Palmroth, M., additional

Published

2022

11. Spatial filtering in a 6D hybrid-Vlasov scheme for alleviating AMR artifacts (in discussion)

Author

Papadakis, K., Pfau-Kempf, Y., Ganse, U., Battarbee, M., Alho, M., Grandin, M., Dubart, M., Turc, L., Zhou, H., Horaites, K., Zaitsev, I., Cozzani, G., Bussov, M., Gordeev, E., Tesema, F., George, H., Suni, J, Tarvus, V., and Palmroth, M.

Published

2022

12. Connection Between Foreshock Structures and the Generation of Magnetosheath Jets: Vlasiator Results

Author

Suni, J., primary, Palmroth, M., additional, Turc, L., additional, Battarbee, M., additional, Johlander, A., additional, Tarvus, V., additional, Alho, M., additional, Bussov, M., additional, Dubart, M., additional, Ganse, U., additional, Grandin, M., additional, Horaites, K., additional, Manglayev, T., additional, Papadakis, K., additional, Pfau‐Kempf, Y., additional, and Zhou, H., additional

Published

2021

13. Magnetosheath jet evolution as a function of lifetime: Global hybrid-Vlasov simulations compared to MMS observations

Author

Palmroth, M., Raptis, S., Suni, J., Karlsson, T., Turc, L., Johlander, A., Ganse, U., Pfau-Kempf, Y., Blanco-Cano, X., Akhavan-Tafti, M., Battarbee, M., Dubart, M., Grandin, M., Tarvus, V., and Osmane, A.

Published

2021

14. Connection Between Foreshock Structures and the Generation of Magnetosheath Jets : Vlasiator Results

Author

Suni, J., Palmroth, M., Turc, L., Battarbee, M., Johlander, Andreas, Tarvus, V, Alho, M., Bussov, M., Dubart, M., Ganse, U., Grandin, M., Horaites, K., Manglayev, T., Papadakis, K., Pfau-Kempf, Y., Zhou, H., Suni, J., Palmroth, M., Turc, L., Battarbee, M., Johlander, Andreas, Tarvus, V, Alho, M., Bussov, M., Dubart, M., Ganse, U., Grandin, M., Horaites, K., Manglayev, T., Papadakis, K., Pfau-Kempf, Y., and Zhou, H.

Abstract

Earth's magnetosheath consists of shocked solar wind plasma that has been compressed and slowed down at the Earth's bow shock. Magnetosheath jets are pulses of enhanced dynamic pressure in the magnetosheath. Jets have been observed by numerous spacecraft missions, but their origin has remained unconfirmed, though several formation mechanisms have been suggested. In this study, we use a method for automatically identifying and tracking jets as well as foreshock compressive structures (FCSs) in four 2D runs of the global hybrid-Vlasov simulation Vlasiator. We find that up to 75% of magnetosheath jets are caused by FCSs impacting the bow shock. These jets propagate deeper into the magnetosheath than the remaining 25% of jets that are not caused by FCSs. We conduct a visual case study of one jet that was not caused by FCSs and find that the bow shock was not rippled before the formation of the jet. Plain Language Summary The space around Earth is filled with plasma, the fourth state of matter. Earth's magnetic field shields our planet from the stream of plasma coming from the Sun, the solar wind. The solar wind plasma is slowed down at the Earth's bow shock, before it flows against and around the Earth's magnetic field in the magnetosheath. Sometimes, pulses of high density or velocity can occur in the magnetosheath that have the potential to disturb the inner regions of near-Earth space where many spacecraft orbit. We call these pulses magnetosheath jets. Magnetosheath jets have been observed by many spacecraft over the past few decades, but how they form has remained unclear. In this study, we use the Vlasiator model to simulate plasma in near-Earth space and investigate the origins of magnetosheath jets. We find that the formation of up to 75% of these jets can be explained by compressive structures in the foreshock, a region populated by intense wave activity extending sunward of the quasi-parallel bow shock, where interplanetary magnetic field lines allow shock-ref

Published

2021

15. Connection Between Foreshock Structures and the Generation of Magnetosheath Jets: Vlasiator Results

Author

Suni, J., Palmroth, M., Turc, L., Battarbee, M., Johlander, A., Tarvus, V., Alho, M., Bussov, M., Dubart, M., Ganse, U., Grandin, M., Horaites, K., Manglayev, T., Papadakis, K., Pfau‐Kempf, Y., Zhou, H., Particle Physics and Astrophysics, Space Physics Research Group, Department of Physics, and Doctoral Programme in Particle Physics and Universe Sciences

Subjects

foreshock, Geofysik, Astrophysics::High Energy Astrophysical Phenomena, hybrid-Vlasov, Fusion, Plasma and Space Physics, 114 Physical sciences, magnetosheath, bow shock, magnetosheath jets, Vlasiator, Fusion, plasma och rymdfysik, Geophysics, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics

Abstract

Earth’s magnetosheath consists of shocked solar wind plasma that has been compressed and slowed down at the Earth’s bow shock. Magnetosheath jets are pulses of enhanced dynamic pressure in the magnetosheath. Jets have been observed by numerous spacecraft missions, but their origin has remained unconfirmed, though several formation mechanisms have been suggested. In this study, we use a method for automatically identifying and tracking jets as well as foreshock compressive structures (FCSs) in four 2D runs of the global hybrid-Vlasov simulation Vlasiator. We find that up to 75% of magnetosheath jets are caused by FCSs impacting the bow shock. These jets propagate deeper into the magnetosheath than the remaining 25% of jets that are not caused by FCSs. We conduct a visual case study of one jet that was not caused by FCSs and find that the bow shock was not rippled before the formation of the jet. Earth's magnetosheath consists of shocked solar wind plasma that has been compressed and slowed down at the Earth's bow shock. Magnetosheath jets are pulses of enhanced dynamic pressure in the magnetosheath. Jets have been observed by numerous spacecraft missions, but their origin has remained unconfirmed, though several formation mechanisms have been suggested. In this study, we use a method for automatically identifying and tracking jets as well as foreshock compressive structures (FCSs) in four 2D runs of the global hybrid-Vlasov simulation Vlasiator. We find that up to 75% of magnetosheath jets are caused by FCSs impacting the bow shock. These jets propagate deeper into the magnetosheath than the remaining 25% of jets that are not caused by FCSs. We conduct a visual case study of one jet that was not caused by FCSs and find that the bow shock was not rippled before the formation of the jet. Plain Language Summary The space around Earth is filled with plasma, the fourth state of matter. Earth's magnetic field shields our planet from the stream of plasma coming from the Sun, the solar wind. The solar wind plasma is slowed down at the Earth's bow shock, before it flows against and around the Earth's magnetic field in the magnetosheath. Sometimes, pulses of high density or velocity can occur in the magnetosheath that have the potential to disturb the inner regions of near-Earth space where many spacecraft orbit. We call these pulses magnetosheath jets. Magnetosheath jets have been observed by many spacecraft over the past few decades, but how they form has remained unclear. In this study, we use the Vlasiator model to simulate plasma in near-Earth space and investigate the origins of magnetosheath jets. We find that the formation of up to 75% of these jets can be explained by compressive structures in the foreshock, a region populated by intense wave activity extending sunward of the quasi-parallel bow shock, where interplanetary magnetic field lines allow shock-reflected particles to travel back toward the Sun.

16. Quasi-Parallel Shock Reformation Seen by Magnetospheric Multiscale and Ion-Kinetic Simulations.

Author

Johlander A, Battarbee M, Turc L, Ganse U, Pfau-Kempf Y, Grandin M, Suni J, Tarvus V, Bussov M, Zhou H, Alho M, Dubart M, George H, Papadakis K, and Palmroth M

Abstract

Shock waves in collisionless plasmas are among the most efficient particle accelerators in space. Shock reformation is a process important to plasma heating and acceleration, but direct observations of reformation at quasi-parallel shocks have been lacking. Here, we investigate Earth's quasi-parallel bow shock with observations by the four Magnetospheric Multiscale spacecraft. The multi-spacecraft observations provide evidence of short large-amplitude magnetic structures (SLAMS) causing reformation of the quasi-parallel shock. We perform an ion-kinetic Vlasiator simulation of the bow shock and show that SLAMS reforming the bow shock recreates the multi-spacecraft measurements. This provides a method for identifying shock reformation in the future., (© 2022. The Authors.)

Published

2022