Peculiar Orbital Characteristics of Earth Quasi-Satellite 469219 Kamo‘oalewa: Implications for the Yarkovsky Detection and Orbital Uncertainty Propagation

Hu, Shoucun; Li, Bin; Jiang, Haoxuan; Bao, Gang; Ji, Jianghui

doi:10.3847/1538-3881/acf8cc

Cited by 4 publications

(1 citation statement)

References 50 publications

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“…Tianwen-2 targets the near-Earth asteroid 2016 HO 3 (469219 Kamo'oalewa), with a diameter of about 40-100 m, and MBC 311P/PANSTARRS, with a diameter of about 320-585 m [12]. Asteroid 2016 HO 3 became a quasi-satellite of the Earth 100 years ago and will remain in this orbit for the next 300 years [61,62].…”

Section: Tianwen-2 Missionmentioning

confidence: 99%

Applications of Ground-Penetrating Radar in Asteroid and Comet Exploration

Guan,

Su,

et al. 2024

Remote Sensing

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Nowadays, asteroid and comet exploration is one of the most important components of deep space exploration. Through asteroid and comet exploration missions, it is possible to reveal the history of the formation and evolution of the solar system, to understand the origin and evolution of the planets, and to improve scientific models and instruments. As a payload with the advantages of non-destructive, penetrating, and polarizing characteristics, ground-penetrating radar (GPR) has been widely used in lunar and Mars exploration, and will play an important role in planned asteroid and comet exploration missions. In this study, statistics on asteroid and comet exploration missions, scientific results, and space-based ground-penetrating radar (SB-GPR) utilization are presented for the three phases to date. According to the statistics, SB-GPR will play an important role in future Phase 2 and 3 missions. The focus of this study is on analyzing the mission flow, SB-GPR parameters, scientific objectives, and scientific results of the missions that have carried SB-GPR and those that are planned to carry SB-GPR, including the Hera, Rosetta, Castalia, and Tianwen-2 missions. On this basis, the development trends of asteroid and comet exploration missions, as well as the future development trends of SB-GPR design and signal interpretation, are discussed.

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Section: Tianwen-2 Missionmentioning

confidence: 99%

Applications of Ground-Penetrating Radar in Asteroid and Comet Exploration

Guan,

Su,

et al. 2024

Remote Sensing

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An automated procedure for the detection of the Yarkovsky effect and results from the ESA NEO Coordination Centre

Fenucci,

Micheli,

Gianotto

et al. 2024

A&A

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The measurement of the Yarkovsky effect on near-Earth asteroids (NEAs) is common practice in orbit determination today, and the number of detections will increase with the developments of new and more accurate telescopic surveys. However, the process of finding new detections and identifying spurious ones is not yet automated, and it often relies on personal judgment. We aim to introduce a more automated procedure that can search for NEA candidates to measure the Yarkovsky effect, and that can identify spurious detections. The expected semi-major axis drift on an NEA caused by the Yarkovsky effect was computed with a Monte Carlo method on a statistical model of the physical parameters of the asteroid that relies on the most recent NEA population models and data. The expected drift was used to select candidates in which the Yarkovsky effect might be detected, according to the current knowledge of their orbit and the length of their observational arc. Then, a nongravitational acceleration along the transverse direction was estimated through orbit determination for each candidate. If the detected acceleration was statistically significant, we performed a statistical test to determine whether it was compatible with the Yarkovsky effect model. Finally, we determined the dependence on an isolated tracklet. Among the known NEAs, our procedure automatically found 348 detections of the Yarkovsky effect that were accepted. The results are overall compatible with the predicted trend with the the inverse of the diameter, and the procedure appears to be efficient in identifying and rejecting spurious detections. This algorithm is now adopted by the ESA NEO Coordination Centre to periodically update the catalogue of NEAs with a measurable Yarkovsky effect, and the results are automatically posted on the web portal.

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Orbit determination of asteroid (469219) Kamo‘oalewa using a combination of historical and new observations

Huang,

Liu,

et al. 2024

Monthly Notices of the Royal Astronomical Society

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The orbit solution of near-Earth asteroids heavily relies on ground-based optical observations. The orbit uncertainty is limited by the insufficient observation quantity and quality. The Chinese Tianwen-2 mission targets a near earth asteroid (469219) Kamo‘oalewa and a main belt comet, 311P/PANSTARRS. To accurately determine the orbit of Kamo‘oalewa, more optical observations are needed. Autonomous observation experiments focusing on Kamo‘oalewa were carried out using the 2.16 m telescope at the Xinglong Observatory of the National Astronomical Observatory of China. We found that this telescope could observe near-Earth asteroids as faint as a magnitude of 22.8. Based on the stacking method and trailed star extraction algorithm, fourteen optical observations were obtained from 2022 to 2024. The orbit for Kamo‘oalewa was determined by combining our observations with historical observations between 2004 and 2024. The inclusion of our observations results in improved orbital uncertainties of Kamo‘oalewa by 18.67 km, 7.93 km, and 11.12 km (1σ) in the X, Y, and Z directions, respectively. Furthermore, by combining all existed and simulated observations, the uncertainty of the orbital determination of Kamo‘oalewa was analysed. When using an additional 180 group observations from three Chinese observatories over two years, the orbital uncertainties of Kamo‘oalewa in the three directions could be reduced to 30 km (1σ).

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Peculiar Orbital Characteristics of Earth Quasi-Satellite 469219 Kamo‘oalewa: Implications for the Yarkovsky Detection and Orbital Uncertainty Propagation

Cited by 4 publications

References 50 publications

Applications of Ground-Penetrating Radar in Asteroid and Comet Exploration

Applications of Ground-Penetrating Radar in Asteroid and Comet Exploration

An automated procedure for the detection of the Yarkovsky effect and results from the ESA NEO Coordination Centre

Orbit determination of asteroid (469219) Kamo‘oalewa using a combination of historical and new observations

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