Long-term Stable Equilibria for Synchronous Binary Asteroids

TL;DR

This paper explores the long-term stable equilibrium of synchronous binary asteroids where tidal and BYORP torques balance, providing insights into asteroid geophysics and challenging existing models.

Contribution

It introduces the concept of a long-term stable equilibrium for binary asteroids and links observational data to asteroid geophysical properties, challenging canonical models.

Findings

Existence of a long-term stable equilibrium for binary asteroids.

Observed binary populations align with the rubble pile model.

Discrepancy between predicted and observed tidal Love numbers.

Abstract

Synchronous binary asteroids may exist in a long-term stable equilibrium, where the opposing torques from mutual body tides and the binary YORP (BYORP) effect cancel. Interior of this equilibrium, mutual body tides are stronger than the BYORP effect and the mutual orbit semi-major axis expands to the equilibrium; outside of the equilibrium, the BYORP effect dominates the evolution and the system semi-major axis will contract to the equilibrium. If the observed population of small (0.1 - 10 km diameter) synchronous binaries are in static configurations that are no longer evolving, then this would be confirmed by a null result in the observational tests for the BYORP effect. The confirmed existence of this equilibrium combined with a shape model of the secondary of the system enables the direct study of asteroid geophysics through the tidal theory. The observed synchronous asteroid population cannot exist in this equilibrium if described by the canonical "monolithic" geophysical model. The "rubble pile" geophysical model proposed by \citet{Goldreich2009} is sufficient, however it predicts a tidal Love number directly proportional to the radius of the asteroid, while the best fit to the data predicts a tidal Love number inversely proportional to the radius. This deviation from the canonical and \citet{Goldreich2009} models motivates future study of asteroid geophysics. Ongoing BYORP detection campaigns will determine whether these systems are in an equilibrium, and future determination of secondary shapes will allow direct determination of asteroid geophysical parameters.