Your search keyword '"Dargent, Jeremy"' showing total 9 results

1. Simulation of plasmaspheric plume impact on dayside magnetic reconnection

Author

Dargent, Jérémy, Aunai, Nicolas, Lavraud, Benoît, Toledo-Redondo, Sergio, and Califano, Francesco

Subjects

Physics - Plasma Physics, Physics - Space Physics

Abstract

During periods of strong magnetic activity, cold dense plasma from the plasmasphere typically forms a plume extending towards the dayside magnetopause, eventually reaching it. In this work, we present a large-scale two-dimensional fully kinetic Particle-In-Cell simulation of a reconnecting magnetopause hit by a propagating plasmaspheric plume. The simulation is designed so that it undergoes four distinct phases: initial unsteady state, steady state prior to plume arrival at the magnetospause, plume interaction and steady state once the plume is well engulfed in the reconnection site. We show the evolution of the magnetopause's dynamics subjected to the modification of the inflowing plasma. Our main result is that the change in the plasma temperature (cold protons in the plume) have no effects on the magnetic reconnection rate, which on average depends only on the inflowing magnetic field and total ion density, before, during and after the impact., Comment: Letter, 13 pages, 2 figures, 1 table

Published

2020

2. Interplay between Kelvin-Helmholtz and Lower-Hybrid Drift instabilities

Author

Dargent, Jérémy, Lavorenti, Federico, Califano, Francesco, Henri, Pierre, Pucci, Francesco, and Cerri, Silvio S.

Subjects

Physics - Plasma Physics, Astrophysics - Earth and Planetary Astrophysics

Abstract

Boundary layers in space and astrophysical plasmas are the location of complex dynamics where different mechanisms coexist and compete eventually leading to plasma mixing. In this work, we present fully kinetic Particle-In-Cell simulations of different boundary layers characterized by the following main ingredients: a velocity shear, a density gradient and a magnetic gradient localized at the same position. In particular, the presence of a density gradient drives the development of the lower hybrid drift instability (LHDI), which competes with the Kelvin-Helmholtz instability (KHI) in the development of the boundary layer. Depending on the density gradient, the LHDI can even dominate the dynamics of the layer. Because these two instabilities grow on different spatial and temporal scales, when the LHDI develops faster than the KHI an inverse cascade is generated, at least in 2D. This inverse cascade, starting at the LHDI kinetic scales, generates structures at scale lengths at which the KHI would typically develop. When that is the case, those structures can suppress the KHI itself because they significantly affect the underlying velocity shear gradient. We conclude that depending on the density gradient, the velocity jump and the width of the boundary layer, the LHDI in its nonlinear phase can become the primary instability for plasma mixing. These numerical simulations show that the LHDI is likely to be a dominant process at the magnetopause of Mercury. These results are expected to be of direct impact to the interpretation of the forthcoming BepiColombo observations., Comment: Research paper accepted at Journal of Plasma Physics, 18 pages, 6 figures and 3 tables

Published

2019

3. A numerical study of tearing instability growth rate as a function of current sheet thickness in the kinetic regime

Author

Innocenti, Maria Elena, primary, Pucci, Fulvia, additional, Boella, Elisabetta, additional, Tenerani, Anna, additional, and Dargent, Jeremy, additional

Published

2023

4. Energy conversion by magnetic reconnection in multiple ion temperature plasmas

Author

Dargent, Jeremy, primary, Toledo-Redondo, Sergio, additional, Divin, Andrey, additional, and Innoncenti, Maria Elena, additional

Published

2023

5. Cold Ion Demagnetization near the X-line of Magnetic Reconnection

Author

Toledo-Redondo, Serio, Andre, Mats, Khotyaintsev, Yuri V, Vaivads, Andris, Walsh, Andrew, Li, Wenya, Graham, Daniel B, Lavraud, Benoit, Masson, Arnaud, Aunai, Nicolas, Divin, Andrey, Dargent, Jeremy, Fuselier, Stephen, Gershman, Daniel J, Dorelli, John, Giles, Barbara, Avanov, Levon, Pollock, Craig, Saito, Yoshifumi, Moore, Thomas E, Coffey, Victoria, Chandler, Michael O, Lindqvist, Per-Arne, Torbert, Roy, and Russell, Christopher T

Subjects

Astrophysics

Abstract

Although the effects of magnetic reconnection in magnetospheres can be observed at planetary scales, reconnection is initiated at electron scales in a plasma. Surrounding the electron diffusion region, there is an Ion-Decoupling Region (IDR) of the size of the ion length scales (inertial length and gyroradius). Reconnection at the Earths magnetopause often includes cold magnetospheric (few tens of eV), hot magnetospheric (10 keV), and magnetosheath (1 keV) ions, with different gyroradius length scales. We report observations of a subregion inside the IDR of the size of the cold ion population gyroradius (approx. 15 km) where the cold ions are demagnetized and accelerated parallel to the Hall electric field. Outside the subregion, cold ions follow the E x B motion together with electrons, while hot ions are demagnetized. We observe a sharp cold ion density gradient separating the two regions, which we identify as the cold and hot IDRs.

Published

2016

6. MMS Observations of Multiscale Hall Physics in the Magnetotail

Author

Alm, Love, André, Mats, Graham, Daniel B., Khotyaintsev, Yuri V., Vaivads, Andris, Chappell, Charles R., Dargent, Jeremy, Fuselier, Stephen A., Haaland, Stein, Lavraud, Benoit, Li, Wenya, Tenfjord, Paul, Toledo-Redondo, Sergio, Vines, Sarah K., Alm, Love, André, Mats, Graham, Daniel B., Khotyaintsev, Yuri V., Vaivads, Andris, Chappell, Charles R., Dargent, Jeremy, Fuselier, Stephen A., Haaland, Stein, Lavraud, Benoit, Li, Wenya, Tenfjord, Paul, Toledo-Redondo, Sergio, and Vines, Sarah K.

Abstract

We present Magnetospheric Multiscale mission (MMS) observations of Hall physics in the magnetotail, which compared to dayside Hall physics is a relatively unexplored topic. The plasma consists of electrons, moderately cold ions (T similar to 1.5 keV) and hot ions (T similar to 20 keV). MMS can differentiate between the cold ion demagnetization region and hot ion demagnetization regions, which suggests that MMS was observing multiscale Hall physics. The observed Hall electric field is compared with a generalized Ohm's law, accounting for multiple ion populations. The cold ion population, despite its relatively high initial temperature, has a significant impact on the Hall electric field. These results show that multiscale Hall physics is relevant over a much larger temperature range than previously observed and is relevant for the whole magnetosphere as well as for other astrophysical plasma.

Published

2019

7. Perpendicular Current Reduction Caused by Cold Ions of Ionospheric Origin in Magnetic Reconnection at the Magnetopause : Particle-in-Cell Simulations and Spacecraft Observations

Author

Toledo-Redondo, Sergio, Dargent, Jeremy, Aunai, Nicolas, Lavraud, Benoit, André, Mats, Li, Wenya, Giles, Barbara, Lindqvist, Per-Arne, Ergun, Robert E., Russell, Christopher T., Burch, James L., Toledo-Redondo, Sergio, Dargent, Jeremy, Aunai, Nicolas, Lavraud, Benoit, André, Mats, Li, Wenya, Giles, Barbara, Lindqvist, Per-Arne, Ergun, Robert E., Russell, Christopher T., and Burch, James L.

Abstract

Cold ions of ionospheric origin are present throughout the Earth's magnetosphere, including the dayside magnetopause, where they modify the properties of magnetic reconnection, a major coupling mechanism at work between the magnetosheath and the magnetosphere. We present Magnetospheric MultiScale (MMS) spacecraft observations of the reconnecting magnetopause with different amounts of cold ions and show that their presence reduces the Hall term in the Ohm's law. Then, we compare two particle-in-cell simulations, with and without cold ions on the magnetospheric side. The cold ions remain magnetized inside the magnetospheric separatrix region, leading to the reduction of the perpendicular currents associated with the Hall effect. Moreover, this reduction is proportional to the relative number density of cold ions. And finally, the Hall electric field peak is reduced along the magnetospheric separatrix owing to cold ions. This should have an effect on energy conversion by reconnection from electromagnetic fields to kinetic energy of the particles. Plain Language Summary The magnetic field of Earth creates a natural boundary that isolates and protects us from the particles and fields coming from the Sun, typically known as the solar wind. This natural shield is called the magnetosphere and is filled by plasma. The particles are coming from the solar wind and are usually deviated around the magnetosphere. However, various mechanisms are capable of interconnecting these two regions of plasma, permitting the exchange of mass and energy. Magnetic reconnection is a primary coupling mechanism and the driver of storms and substorms inside the magnetosphere. In this work, we investigate what occurs when particles of very low energy (cold ions) of ionospheric origin reach the reconnecting boundary between the solar wind and the magnetosphere. We use both spacecraft observations and numerical simulations, and we find that they modify the way reconnection operates, by reducing the

Published

2018

8. Energy budget and mechanisms of cold ion heating in asymmetric magnetic reconnection

Author

Toledo-Redondo, Sergio, André, Mats, Khotyaintsev, Yuri V., Lavraud, Benoit, Vaivads, Andris, Graham, Daniel B., Li, Wenya, Perrone, Denise, Fuselier, Stephen, Gershman, Daniel J., Aunai, Nicolas, Dargent, Jeremy, Giles, Barbara, Le Contel, Olivier, Lindqvist, Per-Arne, Ergun, Robert E., Russell, Christopher T., Burch, James L., Toledo-Redondo, Sergio, André, Mats, Khotyaintsev, Yuri V., Lavraud, Benoit, Vaivads, Andris, Graham, Daniel B., Li, Wenya, Perrone, Denise, Fuselier, Stephen, Gershman, Daniel J., Aunai, Nicolas, Dargent, Jeremy, Giles, Barbara, Le Contel, Olivier, Lindqvist, Per-Arne, Ergun, Robert E., Russell, Christopher T., and Burch, James L.

Abstract

Cold ions (few tens of eV) of ionospheric origin are commonly observed on the magnetospheric side of the Earth's dayside magnetopause. As a result, they can participate in magnetic reconnection, changing locally the reconnection rate and being accelerated and heated. We present four events where cold ion heating was observed by the Magnetospheric Multiscale mission, associated with the magnetospheric Hall E field region of magnetic reconnection. For two of the events the cold ion density was small compared to the magnetosheath density, and the cold ions were heated roughly to the same temperature as magnetosheath ions inside the exhaust. On the other hand, for the other two events the cold ion density was comparable to the magnetosheath density and the cold ion heating observed was significantly smaller. Magnetic reconnection converts magnetic energy into particle energy, and ion heating is known to dominate the energy partition. We find that at least 10-25% of the energy spent by reconnection into ion heating went into magnetospheric cold ion heating. The total energy budget for cold ions may be even higher when properly accounting for the heavier species, namely helium and oxygen. Large E field fluctuations are observed in this cold ion heating region, i.e., gradients and waves, that are likely the source of particle energization. Plain Language Summary: The magnetic field of Earth creates a natural shield that isolates and protects us from the particles and fields coming from our star, the Sun. This natural shield is called the magnetosphere and is filled by plasma. The particles coming from the Sun form another plasma called the solar wind and are usually deviated around the magnetosphere. However, under certain circumstances these two plasmas can reconnect (magnetic reconnection), and part of the energy and mass of the two plasmas is interchanged. Magnetic reconnection is the driver of storms and substorms inside the magnetosphere. In this work, we investigate

Published

2017

9. Cold ion demagnetization near the X-line of magnetic reconnection

Author

Toledo-Redondo, Sergio, Andre, Mats, Khotyaintsev, Yuri V., Vaivads, Andris, Walsh, Andrew, Li, Wenya, Graham, Daniel B., Lavraud, Benoit, Masson, Arnaud, Aunai, Nicolas, Divin, Andrey, Dargent, Jeremy, Fuselier, Stephen, Gershman, Daniel J., Dorelli, John, Giles, Barbara, Avanov, Levon, Pollock, Craig, Saito, Yoshifumi, Moore, Thomas E., Coffey, Victoria, Chandler, Michael O., Lindqvist, Per-Arne, Torbert, Roy, Russell, Christopher T., Toledo-Redondo, Sergio, Andre, Mats, Khotyaintsev, Yuri V., Vaivads, Andris, Walsh, Andrew, Li, Wenya, Graham, Daniel B., Lavraud, Benoit, Masson, Arnaud, Aunai, Nicolas, Divin, Andrey, Dargent, Jeremy, Fuselier, Stephen, Gershman, Daniel J., Dorelli, John, Giles, Barbara, Avanov, Levon, Pollock, Craig, Saito, Yoshifumi, Moore, Thomas E., Coffey, Victoria, Chandler, Michael O., Lindqvist, Per-Arne, Torbert, Roy, and Russell, Christopher T.

Abstract

Although the effects of magnetic reconnection in magnetospheres can be observed at planetary scales, reconnection is initiated at electron scales in a plasma. Surrounding the electron diffusion region, there is an Ion-Decoupling Region (IDR) of the size of the ion length scales (inertial length and gyroradius). Reconnection at the Earth's magnetopause often includes cold magnetospheric (few tens of eV), hot magnetospheric (10keV), and magnetosheath (1keV) ions, with different gyroradius length scales. We report observations of a subregion inside the IDR of the size of the cold ion population gyroradius (approximate to 15km) where the cold ions are demagnetized and accelerated parallel to the Hall electric field. Outside the subregion, cold ions follow the E x B motion together with electrons, while hot ions are demagnetized. We observe a sharp cold ion density gradient separating the two regions, which we identify as the cold and hot IDRs., QC 20161011

Published

2016