Hirabayashi, Masatoshi and Tatsumi, Eri and Miyamoto, Hideaki and Komatsu, Goro and Sugita, Seiji and Watanabe, Sei-ichiro and Scheeres, Daniel J. and Barnouin, Olivier S. and Michel, Patrick and Honda, Chikatoshi and Michikami, Tatsuhiro and Cho, Yuichiro and Morota, Tomokatsu and Hirata, Naru and Hirata, Naoyuki and Sakatani, Naoya and Schwartz, Stephen R. and Honda, Rie and Yokota, Yasuhiro and Kameda, Shingo and Suzuki, Hidehiko and Kouyama, Toru and Hayakawa, Masahiko and Matsuoka, Moe and Yoshioka, Kazuo and Ogawa, Kazunori and Sawada, Hirotaka and Yoshikawa, Makoto and Tsuda, Yuichi (2019) The Western Bulge of 162173 Ryugu Formed as a Result of a Rotationally Driven Deformation Process. The Astrophysical Journal, 874 (1). L10. ISSN 2041-8213
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Abstract
162173 Ryugu, the target of Hayabusa2, has a round shape with an equatorial ridge, which is known as a spinning top shape. A strong centrifugal force is a likely contributor to Ryugu's top-shaped features. Observations by the Optical Navigation Camera on board Hayabusa2 show a unique longitudinal variation in geomorphology; the western side of this asteroid, later called the western bulge, has a smooth surface and a sharp equatorial ridge, compared to the other side. Here, we propose a structural deformation process that generated the western bulge. Applying the mission-derived shape model, we employ a finite element model technique to analyze the locations that experience structural failure within the present shape. Assuming that materials are uniformly distributed, our model shows the longitudinal variation in structurally failed regions when the spin period is shorter than ∼3.75 hr. Ryugu is structurally intact in the subsurface region of the western bulge while other regions are sensitive to structural failure. We infer that this variation is indicative of the deformation process that occurred in the past, and the western bulge is more relaxed structurally than the other region. Our analysis also shows that this deformation process might occur at a spin period between ∼3.5 and ∼3.0 hr, providing the cohesive strength ranging between ∼4 and ∼10 Pa.
Item Type: | Article |
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Subjects: | European Scholar > Physics and Astronomy |
Depositing User: | Managing Editor |
Date Deposited: | 05 Jun 2023 04:21 |
Last Modified: | 20 Jan 2024 10:23 |
URI: | http://article.publish4promo.com/id/eprint/1868 |