Formation of Kuiper Belt Binaries

Abstract

The discovery that a substantial fraction of Kuiper Belt objects (KBOs) exists in binaries with wide separations and roughly equal masses, has motivated a variety of new theories explaining their formation. Goldreich et al. (2002) proposed two formation scenarios: In the first, a transient binary is formed, which becomes bound with the aid of dynamical friction from the sea of small bodies (L2s mechanism); in the second, a binary is formed by three body gravitational deflection (L3 mechanism). Here, we accurately calculate the L2s and L3 formation rates for sub-Hill velocities. While the L2s formation rate is close to previous order of magnitude estimates, the L3 formation rate is about a factor of 4 smaller. For sub-Hill KBO velocities (v << vH) the ratio of the L3 to the L2s formation rate is 0.05 (v/vH) independent of the small bodies' velocity dispersion, their surface density or their mutual collisions. For Super-Hill velocities (v >> vH) the L3 mechanism dominates over the L2s mechanism. Binary formation via the L3 mechanism competes with binary destruction by passing bodies. Given sufficient time, a statistical equilibrium abundance of binaries forms. We show that the frequency of long-lived transient binaries drops exponentially with the system's lifetime and that such transient binaries are not important for binary formation via the L3 mechanism, contrary to Lee et al. (2007). For the L2s mechanism we find that the typical time, transient binaries must last, to form Kuiper Belt binaries (KBBs) for a given strength of dynamical friction, D, increases only logarithmically with D. Longevity of transient binaries only becomes important for very weak dynamical friction (i.e. D 0.002) and is most likely not crucial for KBB formation.