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-PS04] Regolith Science

コンビーナ:和田 浩二(千葉工業大学惑星探査研究センター)、中村 昭子(神戸大学大学院理学研究科地球惑星科学専攻)、Patrick Michel(Universite Cote D Azur Observatoire De La Cote D Azur CNRS Laboratoire Lagrange)、Kevin John Walsh(Southwest Research Institute Boulder)

[PPS04-05] Thermophysical property of the artificial impact crater on asteroid Ryugu

*坂谷 尚哉1田中 智1岡田 達明1神山 徹2三浦 昭1平田 成3千秋 博紀4荒井 武彦5嶌生 有理1出村 裕英3須古 健太郎3関口 朋彦6滝田 隼7福原 哲哉8田口 真8Müller Thomas9Hagermann Axel10Biele Jens11Grott Matthias11Hamm Maximilian12,11Delbo Marco13伊藤 瑞生1,19平田 直之14荒川 政彦14小川 和律15,14和田 浩二4門野 敏彦16本田 理恵17白井 慶14佐伯 孝尚1今村 裕志1高木 靖彦18矢野 創1早川 雅彦1岡本 千里14澤田 弘崇1中澤 暁1飯島 祐一1杉田 精司19諸田 智克19山田 学4亀田 真吾8巽 瑛理20横田 康弘1鈴木 秀彦21本田 親寿3吉岡 和夫19松岡 萌1長 勇一郎19 (1.宇宙航空研究開発機構 宇宙科学研究所、2.産業技術総合研究所、3.会津大学、4.千葉工業大学、5.足利大学、6.北海道教育大学、7.北海道北見高校、8.立教大学、9.Max-Planck Institute for Extraterrestrial Physics、10.University of Stirling、11.German Aerospace Center、12.University of Potsdam、13.Observatoire de la Côte d'Azur, CNRS、14.神戸大学、15.JAXA Space Exploration Center、16.産業医科大学、17.高知大学、18.愛知東邦大学、19.東京大学、20.Instituto de Astrofisica de Canarias、21.明治大学)

The Hayabusa2 spacecraft has completed the rendezvous phase around Cb-type asteroid Ryugu in 2019. From thermal infrared imaging by TIR, global temperature distribution of Ryugu is consistent with the thermal calculation with thermal inertia of 300±100 J m-2 K-1 s-0.5 [1], and thermal inertia values of the floors of craters are in general roughly comparable with the global average [2]. On the other hand, few small craters show anomalously low thermal inertia about 50 J m-2 K-1 s-0.5, which might be contributed from the thermal insulating nature of the fine-grained and unconsolidated materials [3]. However, it is unknown how relaxation process of the crater relates to the thermophysical property and physical condition of the surface materials. On April 2019, Hayabusa2 have carried out an artificial impact (Small Carry-on Impactor or SCI) experiment [4], whereby a ~2 kg mass was fired at 2 km/s against the asteroid surface. As a result of the successful operation, an artificial crater (SCI crater) with diameter larger than 10 m was created on the asteroid. In this study, we investigated thermal property of the SCI crater as the freshest crater on Ryugu.

We had acquired TIR images of the SCI crater in some descending sequences (PPTD-TM1A&B operations on May and June, 2019). All of these images showed higher temperature in the SCI crater than surroundings by ~10 K, especially on the western side of the crater. This high temperature would indicate low thermal inertia materials in the crater, or the high solar incident angle on the crater inner wall would make the temperature higher.

Since the number of images and observation duration were limited for each operation, we could not examine diurnal temperature profile of the crater. In order to estimate the thermal inertia of the SCI crater from single thermal image, we conducted surface temperature simulation using a local digital elevation model (DEM) around the SCI crater. With varying thermal inertia, the simulated images were produced, and thermal inertia was estimated by comparison with the simulation results and observed temperature images.

As a result, the simulated temperature distribution inside the SCI crater agrees well with the observed image. In this preliminary analysis, we expect that the thermal inertia in the SCI crater is uniformly about 300 J m-2 K-1 s-0.5, consistent with large boulders (Iijima boulder and Okamoto boulder) in the crater, surrounding materials, and the global average. Therefore, the chief determinant of the high temperature in the SCI crater would not be the change of the thermal inertia.

Diurnal thermal skin depth of Ryugu is a few centimeters, assuming the thermal inertia of 300 J m-2 K-1 s-0.5. Although the inside of the SCI crater seems to be filled with finer grains than the surroundings [4], less change in thermal inertia of the SCI crater compared with the surroundings or top-surface large boulders indicates that the typical grain size of the subsurface layer (meter-scale in depth) is larger than a few centimeters. Furthermore, since the centimeter-sized grains have thermal property consistent with the larger boulders and the small grains are considered to be crushed from the large boulders, the thermophysical property of the boulders is expected to be homogeneous in centimeter-scale or larger.

References: [1] Okada et al. (2019), Proc. Asteroid Science in the Age of Haya-busa2 and OSIRIS-REx, #2092. [2] Shimaki et al. (2019), Proc. Asteroid Science in the Age of Haya-busa2 and OSIRIS-REx, #2050. [3] Sakatani et al. (2019), Proc. Asteroid Science in the Age of Haya-busa2 and OSIRIS-REx, #2189. [4] Arakawa et al. (submitted).