Possible approach to detecting the mysterious Saturnian convective dynamo through gravitational sounding

Abstract: Context. Planetary dynamo research is mathematically and numerically difficult. Forward calculations are numerically expensive and subject to much uncertainty in key magnetohydrodynamics parameters. For a gaseous planet such as Saturn, even the precise location of its dynamo and typical convective strength are unknown, which further complicates studies. Aims. We test the idea of inversely probing Saturnian convective dynamo through gravitational sounding, based on the principle that the convective fluid motion… Show more

“…Although the perspective of reliably detecting normal modes with Doppler tracking of an orbiter is promising for the understanding of planetary interiors (Durante et al 2017(Durante et al , 2022Friedson 2020),we will defer such complex discussion to a future paper. Nor will we discuss the fields that could arise from deepseated mass anomalies, a nonhydrostatic core, or convective dynamo effects (Liu et al 2020). While it is clear that there are nonzonal, nonstatic components of the gravity field of Saturn, here we focus on the determination of the static zonal gravity field and tidal perturbations.…”

The Case for Future Gravity Science Investigations at Saturn with a Planetary Orbiter

“…Although the perspective of reliably detecting normal modes with Doppler tracking of an orbiter is promising for the understanding of planetary interiors (Durante et al 2017(Durante et al , 2022Friedson 2020),we will defer such complex discussion to a future paper. Nor will we discuss the fields that could arise from deepseated mass anomalies, a nonhydrostatic core, or convective dynamo effects (Liu et al 2020). While it is clear that there are nonzonal, nonstatic components of the gravity field of Saturn, here we focus on the determination of the static zonal gravity field and tidal perturbations.…”

The Case for Future Gravity Science Investigations at Saturn with a Planetary Orbiter

“…We have strictly validated LUGREAS software with the well‐known planetary spacecraft POD and dynamical parameters software GEODYN II (Pavlis, 2001; Ye et al., 2016). It has been extended to analyze orbital tracking data from various missions targeting different planetary bodies such as Mars (e.g., Yan, Yang, Ye et al., 2018), Mercury (e.g., J. Yan et al., 2019), asteroids (e.g., Jin et al., 2020) and Saturn (e.g., Liu, Kong et al., 2020). In this study, we will first use LUGREAS to process the radio tracking data from the Chang’e 1 to the Chang’e 4 together.…”

Review of the Precise Orbit Determination for Chinese Lunar Exploration Projects

“…It is widely accepted that planetary magnetic fields are generated in an electrically conducting fluid layer in their deep interiors through the dynamo process (Jones, 2011). Therefore, planetary magnetic fields provide a window to infer the internal structure and dynamics of planets (Stevenson, 1982a, 2003; Guillot, 2005; Schubert and Soderlund, 2011; Liu SH et al, 2020). Among our solar system’s planets, Jupiter exhibits the strongest magnetic field, which is thought to be generated in its metallic hydrogen region (Stevenson, 1982a; Guillot, 2005; Jones et al, 2011).…”

Influence of reference states on Jupiter’s dynamo simulations