Polar confinement of Saturn's magnetosphere revealed by in situ Cassini observations

Pilkington, N. M.; Achilleos, N.; Arridge, C. S.; Masters, A.; Sergis, N.; Coates, A. J.; Dougherty, M. K.

doi:10.1002/2014ja019774

Cited by 23 publications

(45 citation statements)

References 62 publications

(122 reference statements)

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Section: Modeling the Contribution Of Equatorial Ring Currents And Essupporting

confidence: 88%

“…This is consistent with Pilkington et al, 2014Pilkington et al, 's (2014 treatment of in situ data obtained by the Cassini spacecraft between 2007 and 2009, which indicates that the magnetopause boundary at Saturn is best described by a flattened surface along the north-south direction. Just upstream from the cusp, for example, the flattening parameter takes a value of ≈ 0.81: This corresponds to a flattening of the boundary of ≈ 19% and is consistent with Pilkington et al, 2014Pilkington et al, 's (2014 treatment of Cassini data. This value corresponds to a simple dilation to an axisymmetric magnetopause boundary along the north-south direction: Due to the high concentration of low-latitude crossings in the data set, and since a compressed boundary cannot describe the "flaring" of the surface downstream from the cusp, it seems reasonable that we obtain a larger value for the flattening parameter .…”

Section: Modeling the Contribution Of Equatorial Ring Currents And Essupporting

confidence: 88%

“…In the absence of an upstream solar-wind monitor, observed magnetopause crossings were used to model the shape of the boundary including variable solar wind pressure Kanani et al, 2010) and the behavior of the surface in response to variations in the internal plasma pressure distributions (Achilleos et al, 2010;Pilkington et al, 2014;Sorba et al, 2017). In the absence of an upstream solar-wind monitor, observed magnetopause crossings were used to model the shape of the boundary including variable solar wind pressure Kanani et al, 2010) and the behavior of the surface in response to variations in the internal plasma pressure distributions (Achilleos et al, 2010;Pilkington et al, 2014;Sorba et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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A Self‐Regulating Equilibrium Magnetopause Model With Applications to Saturn

2019

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We describe a new method of constructing an equilibrium magnetopause surface based on the pressure balance between external and internal pressure sources. Details are given for every step of the procedure, including the initial pressure balance condition (which determines magnetopause morphology), the related underlying assumptions, and the final optimized magnetopause surface. Our method produces a final equilibrium magnetopause surface that satisfies the local balance between the solar wind dynamic pressure and planetary magnetic pressure with an error no greater than 1%. We also discuss the contribution of hot plasma pressure and equatorial ring currents and their effects on magnetopause morphology. For each optimized magnetopause boundary, we give coefficients for fitted polynomial approximations to allow simple and accurate reproductions for practical applications. We specifically discuss the potential application to the modeling of Saturn's magnetopause and describe how the equilibrium magnetopause model can be used to estimate the compressibility of the boundary.

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Section: Modeling the Contribution Of Equatorial Ring Currents And Essupporting

confidence: 88%

Section: Modeling the Contribution Of Equatorial Ring Currents And Essupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

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A Self‐Regulating Equilibrium Magnetopause Model With Applications to Saturn

2019

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“…Beyond the magnetopause on the dayside, δ usually exceeds 1.0 because the magnetic fields fluctuate from varying solar wind conditions. In fact, this variability serves as a good marker for the magnetopause, and Figure indicates the statistical validity of the model magnetopause (Pilkington et al, ).…”

Section: Bin Sampling and Uncertaintiesmentioning

confidence: 86%

The Meridional Magnetic Field Lines of Saturn

Carbary

2018

JGR Space Physics

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The magnetometer data for the Cassini mission (2004–2016) are used to derive a model of Saturn's meridional magnetic field lines. Using a bin map of the Bρ and Bz field components, the field lines can be traced from the equator to high latitudes in the inner magnetosphere. The traces reveal a magnetic field greatly compressed on the dayside and highly elongated on the nightside, which are presumably the effects of solar wind compression and viscous flow around the magnetosphere. A model of the traced field lines can accommodate this day‐night asymmetry and offer a way to connect various places in the magnetosphere. This model can be adjusted for magnetodisk warping by using solar latitude. The field line traces can be mapped down to the ionosphere using an offset dipole. The dayside magnetopause (L = 21) is mapped to colatitudes of ~13° in the north and ~16° in the south, while for L > 25 on the nightside, the mapped field lines approach asymptotic limits of ~16° in the north and ~18° in the south.

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“…Because of the presence of a disk-like current sheet at Jupiter, Jupiter's magnetospheric boundaries are expected to exhibit strong polar flattening (e.g., Slavin et al 1985;Huddleston et al 1998;Pilkington et al 2014), meaning that the magnetosphere extends further from the planet in the dawn-dusk direction than in the north-south direction. have specifically discussed the issue of polar flattening by use of their Jupiter simulations considering a variety of external conditions.…”

Section: Global Configurationmentioning

confidence: 99%

Solar Wind and Internally Driven Dynamics: Influences on Magnetodiscs and Auroral Responses

et al. 2014

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The dynamics of the giant planet magnetodiscs are strongly influenced by planetary rotation. Yet the solar wind must ultimately remove plasma from these rapidly rotating magnetodiscs at the same rate that plasma is transported radially outward from the source regions: the Io and Enceladus plasma tori. It is not clear how the solar wind influences magnetospheric dynamics when the dynamics are dominated by rotation. However, auroral observations provide important clues. We review magnetodisc sources and radial transport and the solar wind interaction with the giant magnetospheres of Jupiter and Saturn in an attempt to connect auroral features with specific drivers. We provide a discussion of auroral signatures that are related to the solar wind interaction and summarize with a discussion of global magnetospheric dynamics as illustrated by global MHD simulations. Many questions remain and it is the intent of this review to highlight several of the most compelling questions for future research.

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Polar confinement of Saturn's magnetosphere revealed by in situ Cassini observations

Cited by 23 publications

References 62 publications

A Self‐Regulating Equilibrium Magnetopause Model With Applications to Saturn

A Self‐Regulating Equilibrium Magnetopause Model With Applications to Saturn

The Meridional Magnetic Field Lines of Saturn

Solar Wind and Internally Driven Dynamics: Influences on Magnetodiscs and Auroral Responses

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