Your search keyword '"Susanne Flø Spinnangr"' showing total 4 results

1. Magnetospheric Multiscale Observations of an Expanding Oxygen Wave in Magnetic Reconnection

Author

Norah Kaggwa Kwagala, Cecilia Norgren, Paul Tenfjord, Li-Jen Chen, H. Kolsto, Susanne Flø Spinnangr, and Michael Hesse

Subjects

Physics, Geophysics, chemistry, Physics::Plasma Physics, Physics::Space Physics, General Earth and Planetary Sciences, chemistry.chemical_element, Magnetic reconnection, Particle-in-cell, Oxygen, Computational physics

Abstract

Heavier plasma species such as oxygen ions can have a large impact on the magnetic reconnection process. It has been hypothesized that the acceleration of demagnetized oxygen ions by the Hall electric field will lead to the formation of an oxygen wave that expands into the exhaust. By comparing data from NASA's Magnetospheric Multiscale mission to a fully kinetic particle-in-cell simulation, we can for the first time provide observational evidence of such an expanding oxygen wave. The wave is characterized by an oxygen jet consisting of cold ions directed toward the neutral sheet associated with a density cavity. This density cavity forms as the O+ are subject to collective acceleration by the Hall electric field leaving behind a region of low-density oxygen ions. Our results are important for the understanding of the role and effect of oxygen ions in magnetic reconnection. publishedVersion

Published

2021

2. The Impact of Oxygen on the Reconnection Rate

Author

Cecilia Norgren, Susanne Flø Spinnangr, Paul Tenfjord, Michael Hesse, and H. Kolsto

Subjects

Physics, Geophysics, chemistry, Chemical physics, Physics::Space Physics, General Earth and Planetary Sciences, chemistry.chemical_element, Oxygen

Abstract

We investigate the role of a background oxygen population in magnetic reconnection, using particle‐in‐cell simulations. We run several simulations, with different initial oxygen temperatures and densities, to understand how the reconnection rate is influenced, as oxygen is captured by the reconnection process. The oxygen remains approximately demagnetized on the relevant time and spatial scales and therefore has little direct (i.e., immediate mass loading) effect on the reconnection process itself. The reconnection rate is independent of the initial oxygen temperature but clearly dependent on the density. The reduced reconnection rate is twice as fast as predicted by mass loading. We describe a mechanism where the oxygen population (and the associated electrons) acts as an energy sink on the system, altering the energy partitioning. Based on a scaling analysis, we derive an estimate of the reconnection electric field that scales as (1+no/np)−1, where no and np is the oxygen and proton densities, respectively. publishedVersion

Published

2019

3. On the Impact of a Streaming Oxygen Population on Collisionless Magnetic Reconnection

Author

H. Kolsto, Paul Tenfjord, Norah Kaggwa Kwagala, Cecilia Norgren, Michael Hesse, and Susanne Flø Spinnangr

Subjects

Physics, education.field_of_study, Geophysics, chemistry, Physics::Plasma Physics, Physics::Space Physics, Population, General Earth and Planetary Sciences, chemistry.chemical_element, Magnetic reconnection, education, Oxygen, Computational physics

Abstract

Using 2.5-D Particle-In-Cell (PIC) simulations, we investigate how magnetotail reconnection is affected by a cold, streaming, oxygen plasma population, attributed to an ionospheric source, in the inflow region. As the tailward streaming oxygen reaches the current layer, a tailward motion of the reconnection site is induced. Due to the much longer cyclotron period of the oxygen ions, oxygen cannot couple as directly into the reconnection dynamics as protons. We find that the oxygen ions couple indirectly by means of impacting the electron dynamics. Therefore, a demagnetized species can, in fact, alter the dynamics of the reconnection site. We see further that the reconnection rate remains unchanged relative to a nonstreaming run. Our results may prove useful for understanding the development and dynamics of magnetospheric substorms and storms. publishedVersion

Published

2020

4. Collisionless Magnetic Reconnection in an Asymmetric Oxygen Density Configuration

Author

Paul Tenfjord, Michael Hesse, Cecilia Norgren, Norah Kaggwa Kwagala, Susanne Flø Spinnangr, and H. Kolsto

Subjects

Physics, Geophysics, Condensed matter physics, chemistry, Physics::Space Physics, General Earth and Planetary Sciences, chemistry.chemical_element, Magnetic reconnection, Oxygen

Abstract

Combined with the magnetic field, the distribution of charged particles in the inflow region is expected to control the rate of magnetic reconnection. This paper investigates how the reconnection process is altered by a cold, asymmetrically distributed, oxygen population, which is initially located away from the current layer in the inflow regions. A particle-in-cell simulation is used to gain further insight into the dynamics of the system. The time evolution of the reconnection process proceeds rapidly compared to the cyclotron period of O urn:x-wiley:grl:media:grl59941:grl59941-math-0001. Therefore, the oxygen remains, to a good approximation, demagnetized. Thus, Alfvén scaling is not an adequate description of the reconnection rate. A scaling relation for the reconnection rate for an asymmetrically distributed, demagnetized species has been developed. Additionally, we find that an asymmetric density configuration leads to a distinct motion of the reconnection site and generates an asymmetry of the diffusion region and the Hall electric field. publishedVersion

Published

2020