Shape models and dynamical properties of basaltic asteroids outside the dynamical Vesta family

Troianskyi, Volodymyr; Oszkiewicz, Dagmara; Marciniak, Anna; Kankiewicz, Pawel; Fohring, Dora; Galad, Adrian; Kwiatkowski, Tomasz; Skiff, Brian A.; Geier, Stefan; Wilawer, Emil; Moskovitz, Nicholas A.; Gajdos, Stefan; Vilagi, Jozef; Polcic, L'udovit; Kashuba, Volodymyr; Udovichenko, Sergei; Keir, Leonid; Kaminski, Krzysztof; Benishek, Vladimir; Polakis, Tom
Bibliographical reference

European Planetary Science Congress

Advertised on:
9
2021
Number of authors
20
IAC number of authors
1
Citations
0
Refereed citations
0
Description
Through numerical modeling, Nesvorny et al. (2008) showed that asteroids can migrate due to Yarkovsky drift and resonances to outside of the boundaries of the Vesta family. In particular, they found that objects which end up in the scattered resonances region (so-called Cell I, defined by orbital elements 2.2 AU < a < 2.3 AU, 0.05 < e < 0.2, 0 < i deg < 10 deg) typically have retrograde rotations and thermal parameters that maximize Yarkovsky drift rates. These autors also showed, that asteroids migrating to the low inclination region (Cell II defined by 2.32 AU < a < 2.48 AU, 0.05 < e < 0.2, 2 deg < i < 6 deg) should be predominantly prograde rotators.We performe photometric observations and determine spins and shapes of V-type objects in Cell I and Cell II in order to characterize the dynamical properties of these asteroids more accurately. The results of dynamical modelling show that some asteroids may have migrated to their current location from the Vesta family within ~2 Gy. There are objects, however, whose origin in another parent body may also be plausible. This may support the hypothesis that the number of differentiated basaltic objects in the inner and middle Main Belt should be much higher than previously assumed. We will present preliminary results for the first ~10 asteroids in Cell I and Cell II.