Asteroid Thermal Inertia Analyzer

Bojan Novakovic; Marco Fenucci; Dusan Marceta; Debora Pavela

doi:https://doi.org/10.5194/epsc2024-1181

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EPSC Abstracts

Vol. 17, EPSC2024-1181, 2024, updated on 03 Jul 2024

https://doi.org/10.5194/epsc2024-1181

Europlanet Science Congress 2024

© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Poster | Monday, 09 Sep, 10:30–12:00 (CEST), Display time Monday, 09 Sep, 08:30–19:00|

Asteroid Thermal Inertia Analyzer

Bojan Novakovic^1,2, Marco Fenucci^3,4, Dusan Marceta¹, and Debora Pavela¹

Bojan Novakovic et al.

¹Department of Astronomy, Faculty of Mathematics, University of Belgrade, Studentski trg 16, 11000 Belgrade, Serbia (bojan@matf.bg.ac.rs)
²Instituto de Astrofísica de Andalucía (CSIC), Glorieta de la Astronomía s/n, E-18080 Granada, Spain
³ESA ESRIN/PDO/NEO Coordination Centre, Largo Galileo Galilei, 1, I-00044 Frascati (RM), Italy
⁴Elecnor Deimos, Via Giuseppe Verdi, 6, I-28060 San Pietro Mosezzo (NO), Italy

We developed the new model and corresponding publicly available software for determining the surface thermal inertia (TI) of asteroids [1,2]. We named it ASTERIA (Asteroid Thermal Inertia Analyzer). The model allows TI estimation based mostly on population-modeled input parameters in its basic variant. However, as in general cases the model may not work well if all physical parameters are population-based, we identified the set of critical parameters, which includes the diameter, albedo, and rotation periods of an object.

ASTERIA has been validated using data from Bennu and ten other well-characterized NEAs. The results agree well with the literature values, demonstrating the model's reliability for TI analysis.

We have identified a set of 38 near-Earth asteroids (NEAs) for which all the input parameters critical for the ASTERIA model to work reliably are available and presented the new TI for those objects. Among these 38 NEAs, 29 are classified as PHAs. It makes our results highly relevant from the planetary defense point of view. Our sample of new TI estimates also includes 31 sub-kilometer-sized asteroids. At the same time, there are only 17 other literature values in this size range, highlighting the importance of the ASTERIA model for determining the surface TI of small asteroids (see Figure).

A general advantage of the ASTERIA model is that it may be applied to smaller asteroids than TPM, because the Yarkovsky effect is more substantial in smaller objects and, therefore, easier to detect. Additionally, TPM requires thermal infrared observations and good shape models, which are currently challenging for asteroids below some 100 m in size. Based on the astrometric measurements and the detection of Yarkovsky-induced acceleration of orbital motion, it is primarily independent of the most widely used approach for the asteroid TI estimations based on TPM. As such, ASTERIA may also serve as a benchmark test to independently verify the results derived from TPM, one of the long-standing challenges of TPM models [3].

References:

[1] Novakovic, B., Fenucci, M., Marceta, D., and Pavela, D., 2024, PSJ, 5, 11.

[2] Fenucci M., Novaković B., Marčeta D. and Pavela D. 2023 Fenu24/D-NEAs: ASTERIA v1.0.0 Zenodo, doi: 10.5281/zenodo.8365840

[3] Hung D., Hanuš J., Masiero J. R. and Tholen D. J., 2022 PSJ, 3, 56

Acknowledgments

The authors appreciate the support from the Planetary Society STEP grant, made possible by the generosity of the Planetary Society's members.

How to cite: Novakovic, B., Fenucci, M., Marceta, D., and Pavela, D.: Asteroid Thermal Inertia Analyzer, Europlanet Science Congress 2024, Berlin, Germany, 8–13 Sep 2024, EPSC2024-1181, https://doi.org/10.5194/epsc2024-1181, 2024.