Litcius/Paper detail

NEOMOD: A New Orbital Distribution Model for Near-Earth Objects

David Nesvorný, Rogerio Deienno, W. F. Bottke, Robert Jedicke, Shantanu P. Naidu, Steven R. Chesley, P. W. Chodas, Mikael Granvik, David Vokrouhlický, M. Brož, Alessandro Morbidelli, E. Christensen, F. C. Shelly, Bryce Bolin

2023The Astronomical Journal67 citationsDOIOpen Access PDF

Abstract

Abstract Near-Earth Objects (NEOs) are a transient population of small bodies with orbits near or in the terrestrial planet region. They represent a mid-stage in the dynamical cycle of asteroids and comets, which starts with their removal from the respective source regions—the main belt and trans-Neptunian scattered disk—and ends as bodies impact planets, disintegrate near the Sun, or are ejected from the solar system. Here we develop a new orbital model of NEOs by numerically integrating asteroid orbits from main-belt sources and calibrating the results on observations of the Catalina Sky Survey. The results imply a size-dependent sampling of the main belt with the ν 6 and 3:1 resonances producing ≃30% of NEOs with absolute magnitudes H = 15 and ≃80% of NEOs with H = 25. Hence, the large and small NEOs have different orbital distributions. The inferred flux of H < 18 bodies into the 3:1 resonance can be sustained only if the main-belt asteroids near the resonance drift toward the resonance at the maximal Yarkovsky rate (≃2 × 10 −4 au Myr −1 for diameter D = 1 km and semimajor axis a = 2.5 au). This implies obliquities θ ≃ 0° for a < 2.5 au and θ ≃ 180° for a > 2.5 au, both in the immediate neighborhood of the resonance (the same applies to other resonances as well). We confirm the size-dependent disruption of asteroids near the Sun found in previous studies. An interested researcher can use the publicly available NEOMOD Simulator to generate user-defined samples of NEOs from our model.

Topics & Concepts

AsteroidPhysicsPlanetAstrophysicsAsteroid beltNear-Earth objectResonance (particle physics)Solar SystemPopulationSkyAstronomyAbsolute magnitudeFlux (metallurgy)Celestial mechanicsAtomic physicsStarsDemographyMetallurgySociologyMaterials scienceAstro and Planetary SciencePlanetary Science and ExplorationStellar, planetary, and galactic studies