Planetary period oscillations in Saturn's magnetosphere: Examining the relationship between abrupt changes in behavior and solar wind‐induced magnetospheric compressions and expansions

Provan, G.; Tao, Chihiro; Cowley, S. W. H.; Dougherty, M. K.; Coates, A. J.

doi:10.1002/2015ja021642

Cited by 19 publications

(16 citation statements)

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“…However, the two periods crossed each other briefly in late 2009 and started to oscillate around 10.7 hr for four years after equinox (Fischer et al, , ), before the northern hemisphere finally slowed down toward the end of mission (Ye et al, ). Similar developments were also observed in magnetic field perturbations (Andrews et al, ; Cowley & Provan, ; Provan et al, ; Provan et al, ).…”

Section: Introductionsupporting

confidence: 75%

An SLS5 Longitude System Based on the Rotational Modulation of Saturn Radio Emissions

Fischer

Kurth

et al. 2018

Geophysical Research Letters

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Despite the axisymmetry of Saturn's internal field, Saturn radio emissions like Saturn kilometric radiation (SKR) are modulated due to planetary rotation. With the completion of Cassini mission in September 2017, we now have around 14 years of observation of Saturn radio emissions, roughly from southern solstice to northern solstice. In this study, we extend the SLS4 longitude system to the end of the Cassini mission using a phase tracing method. The new Saturn longitude system (SLS5) organizes the observed SKR maxima around 0° subsolar longitude in both northern and southern hemispheres and can be used to organize other phenomena observed in Saturn's magnetosphere, for example, hot plasma injection events. SKR is modulated like a clock when the main source on the morning side is visible. To convert the observed phase to the clock phase, the phase of the morning side source, we also define a second longitude system SLS5*, which takes the spacecraft position into account based on a simple visibility model.

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Section: Introductionsupporting

confidence: 75%

An SLS5 Longitude System Based on the Rotational Modulation of Saturn Radio Emissions

Fischer

Kurth

et al. 2018

Geophysical Research Letters

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“…The period is not constant but rather changes by ~1% over intervals of a year or longer (Galopeau & Lecacheux, ; Gurnett et al, ). Changes in the period are observed in radio emissions (Kurth et al, 2008, 2007; Lamy, ), magnetic fields (Provan et al, , , ), and charged particles (Carbary & Mitchell, 2017; Carbary et al, ). Second, the periodicities themselves are divided into a northern branch and a southern branch, which may have slightly different periods (Andrews et al, ; Carbary et al, ; Gurnett, Lecacheux, et al, ; Gurnett, Persoon, et al, ).…”

Section: Introductionmentioning

confidence: 99%

Energetic Electron Periodicities During the Cassini Grand Finale

et al. 2017

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The Cassini F ring and Proximal orbits took the spacecraft closer to Saturn than any previous mission and allowed determination of energetic charged particles (E > 20 keV) in the inner magnetosphere of the planet. The periodicities of the energetic electrons show a remarkable consistency when analyzed using Lomb periodograms. From the beginning of the F ring orbits in October 2016 to the end of the mission in September 2017, the particles manifest a strong main period of 10.79 h ± 0.01 h, with small Doppler‐related signals slightly above and below this period. The signal‐to‐noise ratio of the main period indicates one of the strongest periods ever seen in Saturn's magnetosphere. As implied by latitude separation, the main period seems to be associated with the northern hemisphere. The 10.79 h period is exactly the same as the single period observed during the early part of the Cassini mission in 2005–6 when Saturn experienced southern summer. A simple rotating searchlight model can simulate the periodograms.

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“…Distinguishing the influence of these systems on phenomena becomes easier during times wherein their modulation periods are most separate. Fortunately for this work, early 2008 represents such a time (see, for example, Provan et al, , Figure 2), with the northern and southern periods being separated by approximately 0.2 h.…”

Section: Discussionmentioning

confidence: 92%

Swept Forward Magnetic Field Variability in High‐Latitude Regions of Saturn's Magnetosphere

et al. 2017

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Swept forward field is the term given to configurations of magnetic field wherein the field lines deviate from the meridional planes of a planet in the direction of its rotation. Evidence is presented for swept‐forward field configurations on Cassini orbits around Saturn from the first half of 2008. These orbits were selected on the basis of high inclination, spatial proximity, and temporal proximity, allowing for the observation of swept‐forward field and resolution of dynamic effects using data from the Cassini magnetometer. Nine orbits are surveyed; all show evidence of swept‐forward field, with typical sweep angle found to be 23°. Evidence is found for transient events that lead to temporary dramatic increases in sweep‐forward angle. The Michigan Solar Wind Model is employed to investigate temporal correlation between the arrivals of solar wind shocks at Saturn with these transient events, with two shown to include instances corresponding with solar wind shock arrivals. Measurements of equatorial electron number density from anode 5 of the Cassini Plasma Spectrometer instrument are investigated for evidence of magnetospheric compression, corresponding with predicted shock arrivals. Potential mechanisms for the transfer of momentum from the solar wind to the magnetosphere are discussed.

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Planetary period oscillations in Saturn's magnetosphere: Examining the relationship between abrupt changes in behavior and solar wind‐induced magnetospheric compressions and expansions

Cited by 19 publications

References 100 publications

An SLS5 Longitude System Based on the Rotational Modulation of Saturn Radio Emissions

An SLS5 Longitude System Based on the Rotational Modulation of Saturn Radio Emissions

Energetic Electron Periodicities During the Cassini Grand Finale

Swept Forward Magnetic Field Variability in High‐Latitude Regions of Saturn's Magnetosphere

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