Global MHD simulations of Neptune's magnetosphere

Mejnertsen, L.; Eastwood, J. P.; Chittenden, J. P.; Masters, A.

doi:10.1002/2015ja022272

Cited by 23 publications

(35 citation statements)

References 81 publications

(121 reference statements)

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“…In particular, the dipole axes of Uranus and Neptune are offset by large angles to their rotation axes (by 60°and 47°, respectively) (Russell & Dougherty, 2010). Coupled with their severe obliquity to the ecliptic plane, these magnetospheres undergo significant reconfiguration both diurnally and seasonally as shown in both observations (e.g., Cowley, 2013) and simulations (e.g., Cao & Paty, 2017;Mejnertsen et al, 2016). More exotically, cases of tidally locked exoplanets and direct evidence of exoplanet magnetic fields suggest the possibility of magnetospheres that, as well as being highly inclined to the stellar wind, are locked-in to this extreme tilted configuration-though such a slow rotation rate might not support a strong planetary dynamo (Grießmeier et al, 2004).…”

Section: 1029/2019ja027510mentioning

confidence: 87%

Dipole Tilt Effect on Magnetopause Reconnection and the Steady‐State Magnetosphere‐Ionosphere System: Global MHD Simulations

et al. 2020

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The Earth's dipole tilt angle changes both diurnally and seasonally and introduces numerous variabilities in the coupled magnetosphere‐ionosphere system. By altering the location and intensity of magnetic reconnection, the dipole tilt influences convection on a global scale. However, due to the nonlinear nature of the system, various other effects like dipole rotation, varying interplanetary magnetic field (IMF) orientation, and nonuniform ionospheric conductance can smear tilt effects arising purely from changes in coupling with the solar wind. To elucidate the underlying tilt angle dependence, we perform magnetohydrodynamic (MHD) simulations of the steady‐state magnetosphere‐ionosphere system under purely southward IMF conditions for tilt angles from 0–90°. We identify the location of the magnetic separator in each case and find that an increasing tilt angle shifts the 3‐D X line southward on the magnetopause due to changes in magnetic shear angle. The separator is highly unsteady above 50° tilt angle, characteristic of regular flux transfer event (FTE) generation on the magnetopause. The reconnection rate drops as the tilt angle becomes large, but remains continuous across the dayside such that the magnetosphere is open even for 90°. These trends map down to the ionosphere, with the polar cap contracting as the tilt angle increases, and region I field‐aligned current (FAC) migrating to higher latitudes with changing morphology. The tilt introduces a north‐south asymmetry in magnetospheric convection, thus driving more FAC in the Northern (sunward facing) hemisphere for large tilt angles than in the Southern independent of conductance. These results highlight the strong sensitivity to onset time in the potential impact of a severe space weather event.

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Section: 1029/2019ja027510mentioning

confidence: 87%

Dipole Tilt Effect on Magnetopause Reconnection and the Steady‐State Magnetosphere‐Ionosphere System: Global MHD Simulations

et al. 2020

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“…The giant magnetospheres of Uranus and Neptune are better described by our toy magnetosphere due to the absence of clear evidence for similarly strong internal plasma sources (Belcher et al, ; Bridge et al, ). The relatively large angles between planetary rotation and magnetic dipole axes and large planetary obliquities at Uranus and Neptune will lead to strong diurnal and seasonal variations in the interaction between each magnetosphere and the solar wind (e.g., Cao & Paty, ; Mejnertsen et al, ). The location of these systems at the largest distances from the Sun suggests considerably more viscous‐like solar wind interactions than at Earth (see Figure ), which may be the dominant driver of magnetospheric dynamics at each of these outermost giant planets.…”

Section: Rationalementioning

confidence: 99%

A More Viscous‐Like Solar Wind Interaction With All the Giant Planets

Masters

2018

Geophysical Research Letters

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Identifying and quantifying the different drivers of energy flow through a planetary magnetosphere is crucial for understanding how each planetary system works. The magnetosphere of our own planet is primarily driven externally by the solar wind through global magnetic reconnection, while a viscous‐like interaction with the solar wind involving growth of the Kelvin‐Helmholtz (K‐H) instability is a secondary effect. Here we consider the solar wind‐magnetosphere interaction at all magnetized planets, exploring the implications of diverse solar wind conditions. We show that with increasing distance from the Sun the electric fields arising from reconnection at the magnetopause boundary of a planetary magnetosphere become weaker, whereas the boundaries become increasingly K‐H unstable. Our results support the possibility of a predominantly viscous‐like interaction between the solar wind and every one of the giant planet magnetospheres, as proposed by previous authors and in contrast with the solar wind‐magnetosphere interaction at Earth.

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“…Gorgon is a 3-D magnetohydrodynamic code, initially developed for studying high energy, collisional plasma interactions such as Z-pinches (Chittenden et al, 2004;Jennings, 2006;Jennings et al, 2010), laser-plasma interactions (Smith et al, 2007), and magnetic tower jets (Ciardi et al, 2007). It has recently been adapted to simulate planetary magnetospheres and their interaction with the solar wind (Mejnertsen et al, 2016).…”

Section: The Gorgon Mhd Codementioning

confidence: 99%

“…In this work, global MHD simulations of the Earth's magnetosphere under variable solar wind are performed using the Gorgon code (Chittenden et al, 2004;Ciardi et al, 2007;Mejnertsen et al, 2016). This work examines the motion of the bow shock.…”

Section: Introductionmentioning

confidence: 99%

Global MHD Simulations of the Earth's Bow Shock Shape and Motion Under Variable Solar Wind Conditions

et al. 2018

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Empirical models of the Earth's bow shock are often used to place in situ measurements in context and to understand the global behavior of the foreshock/bow shock system. They are derived statistically from spacecraft bow shock crossings and typically treat the shock surface as a conic section parameterized according to a uniform solar wind ram pressure, although more complex models exist. Here a global magnetohydrodynamic simulation is used to analyze the variability of the Earth's bow shock under real solar wind conditions. The shape and location of the bow shock is found as a function of time, and this is used to calculate the shock velocity over the shock surface. The results are compared to existing empirical models. Good agreement is found in the variability of the subsolar shock location. However, empirical models fail to reproduce the two‐dimensional shape of the shock in the simulation. This is because significant solar wind variability occurs on timescales less than the transit time of a single solar wind phase front over the curved shock surface. Empirical models must therefore be used with care when interpreting spacecraft data, especially when observations are made far from the Sun‐Earth line. Further analysis reveals a bias to higher shock speeds when measured by virtual spacecraft. This is attributed to the fact that the spacecraft only observes the shock when it is in motion. This must be accounted for when studying bow shock motion and variability with spacecraft data.

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Global MHD simulations of Neptune's magnetosphere

Cited by 23 publications

References 81 publications

Dipole Tilt Effect on Magnetopause Reconnection and the Steady‐State Magnetosphere‐Ionosphere System: Global MHD Simulations

Dipole Tilt Effect on Magnetopause Reconnection and the Steady‐State Magnetosphere‐Ionosphere System: Global MHD Simulations

A More Viscous‐Like Solar Wind Interaction With All the Giant Planets

Global MHD Simulations of the Earth's Bow Shock Shape and Motion Under Variable Solar Wind Conditions

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