O+ and H+ above the polar cap: Observations and semikinetic simulations

Barghouthi, I. A.; Abudayyeh, Hamza; Slapak, Rikard; Nilsson, Hans

doi:10.1002/2015ja021990

Cited by 3 publications

(2 citation statements)

References 88 publications

(141 reference statements)

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“…Finally, from the interpolated electric field, a new velocity is calculated with the Boris algorithm (e.g. Birdsall and Langdon, 1991). The last step is repeated as far as the limitations of the code allow it.…”

Section: Particle Tracing Simulationsmentioning

confidence: 99%

The fate of O+ ions observed in the plasma mantle: particle tracing modelling and cluster observations

et al. 2020

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Abstract. Ion escape is of particular interest for studying the evolution of the atmosphere on geological timescales. Previously, using Cluster-CODIF data, we investigated the oxygen ion outflow from the plasma mantle for different solar wind conditions and geomagnetic activity. We found significant correlations between solar wind parameters, geomagnetic activity (Kp index), and the O+ outflow. From these studies, we suggested that O+ ions observed in the plasma mantle and cusp have enough energy and velocity to escape the magnetosphere and be lost into the solar wind or in the distant magnetotail. Thus, this study aims to investigate where the ions observed in the plasma mantle end up. In order to answer this question, we numerically calculate the trajectories of O+ ions using a tracing code to further test this assumption and determine the fate of the observed ions. Our code consists of a magnetic field model (Tsyganenko T96) and an ionospheric potential model (Weimer 2001) in which particles initiated in the plasma mantle region are launched and traced forward in time. We analysed 131 observations of plasma mantle events in Cluster data between 2001 and 2007, and for each event 200 O+ particles were launched with an initial thermal and parallel bulk velocity corresponding to the velocities observed by Cluster. After the tracing, we found that 98 % of the particles are lost into the solar wind or in the distant tail. Out of these 98 %, 20 % escape via the dayside magnetosphere.

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Section: Particle Tracing Simulationsmentioning

confidence: 99%

The fate of O+ ions observed in the plasma mantle: particle tracing modelling and cluster observations

et al. 2020

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“…At an altitude range of 1.2 Re to 15.2 Re, Barghouthi et al (2016) employed the same 1-D Monte Carlo model used by Abudayyeh et al (2015) to investigate energetic H + and O + outflows along two trajectories (from the polar cap to the cusp) and compared them with Cluster data. Considering the centrifugal acceleration, the ambipolar electric field and the waveparticle interaction, they concluded that the latter was the most important mechanism especially at higher altitudes (cusp).…”

Section: Introductionmentioning

confidence: 99%

The fate of O+ ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations

Schillings¹,

Gunell²,

Nilsson³

et al. 2019

Preprint

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Abstract. Ion escape is of particular interest for studying the evolution of the atmosphere on geological time scales. Previously, using Cluster-CODIF data, we investigated the oxygen ion outflow from the plasma mantle for different solar wind conditions and geomagnetic activity. We found significant correlations between solar wind parameters, geomagnetic activity (Kp index) and the O+ outflow. From these studies, we suggested that O+ ions observed in the plasma mantle and cusp have enough energy and velocity to escape the magnetosphere and be lost into the solar wind or in the distant magnetotail. Thus, this study aims to investigate where do the ions observed in the plasma mantle end up. In order to answer this question, we numerically calculate the trajectories of O+ ions using a tracing code to further test this assumption and determine the fate of the observed ions. Our code consists of a magnetic field model (Tsyganenko T96) and an ionospheric potential model (Weimer 2001) in which particles initiated in the plasma mantle and cusp regions are launched and traced forward in time. We analysed 136 observations of plasma mantle or cusp events in Cluster data between 2001 and 2007, and for each event 200 O+ particles were launched with an initial parallel and perpendicular velocity corresponding to the bulk velocity observed by Cluster. From the observations, our results show that 93 % of the events have an initial parallel velocity component twice the initial perpendicular velocity. After the tracing, we found that 96 % of the particles are lost into the solar wind or in the distant tail. Out of these 96 %, 20 % escape into the dayside magnetosphere.

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Characteristics of Polar Wind Flows at Altitudes of about 20000 km

Чугунин

Клименко

2018

Russ. J. Phys. Chem. B

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O⁺ and H⁺ above the polar cap: Observations and semikinetic simulations

Cited by 3 publications

References 88 publications

The fate of O<sup>+</sup> ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O<sup>+</sup> ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O<sup>+</sup> ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations

Characteristics of Polar Wind Flows at Altitudes of about 20000 km

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O+ and H+ above the polar cap: Observations and semikinetic simulations

Cited by 3 publications

References 88 publications

The fate of O&lt;sup&gt;+&lt;/sup&gt; ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O&lt;sup&gt;+&lt;/sup&gt; ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O&lt;sup&gt;+&lt;/sup&gt; ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations

Characteristics of Polar Wind Flows at Altitudes of about 20000 km

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O⁺ and H⁺ above the polar cap: Observations and semikinetic simulations

The fate of O<sup>+</sup> ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O<sup>+</sup> ions observed in the plasma mantle: particle tracing modelling and cluster observations

The fate of O<sup>+</sup> ions observed in the plasma mantle and cusp: particle tracing modelling and Cluster observations