JpGU-AGU Joint Meeting 2020

講演情報

[E] 口頭発表

セッション記号 P (宇宙惑星科学) » P-PS 惑星科学

[P-PS01] Outer Solar System Exploration Today, and Tomorrow

コンビーナ:木村 淳(大阪大学)、Kunio M. Sayanagi(Hampton University)、土屋 史紀(東北大学大学院理学研究科惑星プラズマ・大気研究センター)、Steven Douglas Vance(NASA Jet Propulsion Laboratory, California Institute of Technology)

[PPS01-12] Ganymedeの強制秤動:粘弾性潮汐変形を考慮したモデル計算

*小島 晋一郎1木村 淳1鎌田 俊一2 (1.大阪大学 大学院理学研究科 宇宙地球科学専攻、2.北海道大学 大学院理学研究院 地球惑星科学部門)

キーワード:Ganymede、秤動、JUICE

Most of solid bodies which are beyond Jupiter are covered by ice and therefore called icy bodies. Based on previous observations and theoretical works, some of these bodies are presumed to possess a subsurface ocean where extraterrestrial organism might exist.
Jovian moon Ganymede is one of these body and is the main target of a future Jovian exploration mission. A past exploration revealed that Ganymede has a small moment of inertia and an intrinsic magnetic field. These observational facts indicate that Ganymede has a fully differentiated interior composed of a metallic core at the center, rocky mantle, and the outermost ice shell. Although a magnetic observation by the past exploration indicates that the salty subsurface ocean exists within the shell, the existence of the ocean is still ambiguous. Therefore, this study uses libration as an alternative method for presuming the interior of Ganymede.
In recent years, a libration study for Ganymede has included an elastic tidal deformation. Consequently, the deformation strongly reduces a librational amplitude in the case with the ocean. On the other hand, the librational amplitude is comparable even in the case without the ocean. Their study concluded the amplitude cannot provide the information of the existence of the ocean. Although other study for Europa included the effect of viscosity, the viscosity profile in the ice shell of its model is considerably simplified, thus a refined model is needed.
In our study, we apply the refined interior model to calculate librational amplitudes and phase-lag including the amplitude and phase-lag of visco-elastic tidal deformations.
As a result, the librational amplitude reaches 110 m for a case with the ocean.
In contrast, the amplitude is up to 10 m for a case without the ocean. These contrasts provide the information of the existence of the ocean.
Also the librational phase-lag is useful to estimate a melting point viscosity at the bottom of the ice shell.
These results will be examined in the next exploration mission named JUICE (JUpiter ICy moons Explorer).