NEOMOD: A New Orbital Distribution Model for Near Earth Objects

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 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.