Cusp dynamics under northward IMF using three‐dimensional global particle‐in‐cell simulations

Cai, Dongsheng; Esmaeili, Amin; Lembège, Bertrand; Nishikawa, Ken‐Ichi

doi:10.1002/2015ja021230

Cited by 14 publications

(36 citation statements)

References 30 publications

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“…The plasma inertia effects is considered in our PIC simulation, as a consequence the length of the simulation box is very much larger than the Debye length λ Dei =(0.11, 0.11), the gyro-radius ρ ce,i =(1. 25,20) and the inertia lengths c ωpe,i = (5, 80)for electrons and ions respectively.…”

Section: Analysis and Discussionmentioning

confidence: 99%

Large Scale Earth’s Bow Shock with Northern IMF as Simulated by PIC Code in Parallel with MHD Model

Baraka¹

2016

J Astrophys Astron

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International audienceIn this paper, we propose a 3D kinetic model (particle-in-cell, PIC) for the description of the large scale Earth’s bow shock. The proposed version is stable and does not require huge or extensive computer resources. Because PIC simulations work with scaled plasma and field parameters, we also propose to validate our code by comparing its results with the available MHD simulations under same scaled solar wind (SW) and (IMF) conditions. We report new results from the two models. In both codes the Earth’s bow shock position is found to be ≈14.8 R E along the Sun–Earth line, and ≈29 R E on the dusk side. Those findings are consistent with past in situ observations. Both simulations reproduce the theoretical jump conditions at the shock. However, the PIC code density and temperature distributions are inflated and slightly shifted sunward when compared to the MHD results. Kinetic electron motions and reflected ions upstream may cause this sunward shift. Species distributions in the foreshock region are depicted within the transition of the shock (measured ≈2 c/ω pi for Θ Bn = 90° and M MS = 4.7) and in the downstream. The size of the foot jump in the magnetic field at the shock is measured to be (1.7c/ω pi ). In the foreshocked region, the thermal velocity is found equal to 213 km s−1 at 15R E and is equal to 63 km s −1 at 12 R E (magnetosheath region). Despite the large cell size of the current version of the PIC code, it is powerful to retain macrostructure of planets magnetospheres in very short time, thus it can be used for pedagogical test purposes. It is also likely complementary with MHD to deepen our understanding of the large scale magnetosphere

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Section: Analysis and Discussionmentioning

confidence: 99%

Large Scale Earth’s Bow Shock with Northern IMF as Simulated by PIC Code in Parallel with MHD Model

Baraka¹

2016

J Astrophys Astron

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“…We used the updated version of the 3D Stanford PIC code (Tristan code) for our simulation 11–14 . For this research, we used the simulation similar to the previous work 15 .…”

Section: Simulation Modelmentioning

confidence: 99%

“…We used the updated version of the 3D Stanford PIC code (Tristan code) for our simulation. [11][12][13][14] For this research, we used the simulation similar to the previous work. 15 The numerical study includes three-dimensional electromagnetic full-particle global simulation model with the time sequence of the IMF rotations as follows: phase (i), from time step 0 to 1,500, there is no IMF and the magnetosphere is generated using a magnetic dipole field; phase (ii), a Northward IMF (Bz = 0.215) is gradually turned on from 1,501 to 1,800.…”

Section: Simulation Modelmentioning

confidence: 99%

“…Since then, many studies including cusp's dynamics and particle precipitations have been done. The cusp is defined as a region of high‐density plasma, highly turbulent and depressed magnetic field, and stagnant flow 10–12 …”

Section: Introductionmentioning

confidence: 99%

“…The cusp is defined as a region of high-density plasma, highly turbulent and depressed magnetic field, and stagnant flow. [10][11][12] The aim of the present simulation study is to investigate the dependence of the energetic charged particles penetration upon solar wind velocity using the updated version of the 3D Stanford PIC code. The specific goals of this study are to estimate the percentage of penetration of the energetic charged particles including electrons and ions in four regions: cusp, plasmasphere, sunward, and tailward reconnection sites.…”

Section: Introductionmentioning

confidence: 99%

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Numerical study of penetration and distribution of charged particles in the magnetosphere during southward IMF case

Esmaeili

Kalaee

Ikram

2020

Contributions to Plasma Physics

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The energetic charged particles penetration in the plasmasphere are carried out using the updated version of 3D Stanford PIC code. We considered slow and fast wind streams to know the penetration of the energetic charged particles (electrons and ions) having different velocities into four regions i.e. cusp, plasmasphere, sunward, and tailward sides. It is observed that the ion penetrations are higher than electrons for solar slow wind streams in the plasmasphere, while it is reverse for the solar fast streams. Also, the results show that the percentage of penetration of the energetic charged particles (both electrons and ions) are the same into the cusp and subsolar point reconnection region. It is different for the higher speed of fast streams; so that the penetrated electrons reached about 10–20 times than penetrated ions. The results show that for the tailward reconnection region, the penetration of ions is 2–3 times higher than the penetration of electrons, but it is the same for the case of higher solar fast speed.

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The Polar Cusps of the Earth's Magnetosphere

Lavraud

Trattner

2021

Geophysical Monograph Series

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Cusp dynamics under northward IMF using three‐dimensional global particle‐in‐cell simulations

Cited by 14 publications

References 30 publications

Large Scale Earth’s Bow Shock with Northern IMF as Simulated by PIC Code in Parallel with MHD Model

Large Scale Earth’s Bow Shock with Northern IMF as Simulated by PIC Code in Parallel with MHD Model

Numerical study of penetration and distribution of charged particles in the magnetosphere during southward IMF case

The Polar Cusps of the Earth's Magnetosphere

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