Centrifugal acceleration at high altitudes above the polar cap: A Monte Carlo simulation

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

doi:10.1002/2015ja021325

Cited by 5 publications

(11 citation statements)

References 64 publications

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“…They found that centrifugal forces increase the outflowing O + flux with 2 orders of magnitude when the convection electric field is enhanced from 0 mV/m to 100 mV/m. A similar result has been shown by Abudayyeh et al (2015), who used a Monte Carlo simulation based on the Tsyganenko T96 model and included the effects of the ambipolar electric field as well as gravitational and mirror forces. Additionally, Abudayyeh et al…”

Section: Introductionsupporting

confidence: 77%

“…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%

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The fate of O<sup>+</sup> 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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Section: Introductionsupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

The fate of O<sup>+</sup> 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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“…In the latter case the divergence of the geomagnetic field lines converts the perpendicular energy into the parallel direction which increases the parallel velocity. Several acceleration mechanisms were studied such as parallel potential drops [Lundin et al, 1995;Maggiolo et al, 2006], centrifugal acceleration [Cladis, 1986;Horwitz et al, 1994;Demars et al, 1996;Nilsson et al, 2008Nilsson et al, , 2010Abudayyeh et al, 2015a] and wave-particle interaction [Chang and Coppi, 1981;Chang et al, 1986;Retterer et al, 1987Retterer et al, , 1994; Barakat and Barghouthi, 1994;Barghouthi, 1997;Barghouthi et al, 1998;Bouhram et al, 2004;Barghouthi and Atout, 2006;Barghouthi, 2008;Barghouthi et al, 2011;Slapak et al, 2011;Waara et al, 2011Waara et al, , 2012Abudayyeh et al, 2015b].…”

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 99%

“…where s is a vector along the magnetic field; V E = E × B∕B 2 is the convection velocity; andb is a unit vector in the direction of the magnetic field . For a detailed description of the effect of centrifugal acceleration on the outflow of ions along various flight trajectories above the polar cap refer to Nilsson et al [2008Nilsson et al [ , 2010 and Abudayyeh et al [2015a].…”

Section: 1002/2015ja021990mentioning

confidence: 99%

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

et al. 2016

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A one‐dimensional direct simulation Monte Carlo model is used to study the outflow of O+ and H+ ions from 1.2 RE to 15.2 RE along two flight trajectories originating from the polar cap, namely, the central polar cap (CPC) and the cusp. To study the effect of varying geophysical conditions and to deduce the proper set of parameters, several parameters were varied, and the results were compared to corresponding data from Cluster spacecraft. First, several sets of diffusion coefficients were considered based on using diffusion coefficients calculated by Barghouthi et al. (1998), Nilsson et al. (2013), and Abudayyeh et al. (2015b) for different altitude intervals. It was found that in the central polar cap using the diffusion coefficients reported by Barghouthi et al. (1998) for altitudes lower than 3.7 RE, zero diffusion coefficients between 3.7 and 7.5 RE and diffusion coefficients from Nilsson et al. (2013) for altitudes higher than 7.5 RE provide the best fit for O+ ions. For O+ ions in the cusp the best fit was obtained for using Barghouthi et al. (1998) diffusion coefficients for altitudes lower than 3.7 RE and Nilsson et al. (2013) diffusion coefficients for altitudes higher than that. The best fit for H+ ions in both regions was obtained by using the diffusion coefficients calculated by Abudayyeh et al. (2015b). Also, it was found that along an ion's trajectory the most recent heating dominates. Second, the strength of centrifugal acceleration was varied by using three values for the ionospheric electric field, namely, 0, 50, and 100 MV/m. It was found that the value of 50 MV/m provided the best fit for both ion species in both regions. Finally, the lower altitude boundary conditions and the electron temperature were varied. Increasing the electron temperature and the lower altitude O+ parallel velocity were found to increase the access of O+ ions to higher altitudes and therefore increase the density at a given altitude. The variation of all other boundary conditions only affected the densities of the ions and not the other moments due to the overwhelming effect of wave‐particle interaction. Furthermore, varying the parameters of one ion species has no effect on the other ion species. We also compared the energy gain per ion due to wave‐particle interaction, centrifugal acceleration, and ambipolar electric field and found that wave‐particle interaction is the most important mechanism, while ambipolar electric field is relatively unimportant especially at higher altitudes.

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Unstable relationships between tree ring δ18O and climate variables over southwestern China: possible impacts from increasing central Pacific SSTs

Liu

Hou

et al. 2018

Theor Appl Climatol

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Centrifugal acceleration at high altitudes above the polar cap: A Monte Carlo simulation

Cited by 5 publications

References 64 publications

The fate of O<sup>+</sup> ions observed in the plasma mantle and cusp: 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

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

Unstable relationships between tree ring δ18O and climate variables over southwestern China: possible impacts from increasing central Pacific SSTs

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Centrifugal acceleration at high altitudes above the polar cap: A Monte Carlo simulation

Cited by 5 publications

References 64 publications

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

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

Unstable relationships between tree ring δ18O and climate variables over southwestern China: possible impacts from increasing central Pacific SSTs

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The fate of O<sup>+</sup> ions observed in the plasma mantle and cusp: 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

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