LONG-TERM STABLE EQUILIBRIA FOR SYNCHRONOUS BINARY ASTEROIDS

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 semimajor axis expands to the equilibrium; outside of the equilibrium, the BYORP effect dominates the evolution and the system semimajor 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 Goldreich and Sari 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 canonicalmore » and Goldreich and Sari 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.« less

[1]  Daniel J. Scheeres,et al.  Radar Imaging of Binary Near-Earth Asteroid (66391) 1999 KW4 , 2006, Science.

[2]  P. Tanga,et al.  Collisions and Gravitational Reaccumulation: Forming Asteroid Families and Satellites , 2001, Science.

[3]  M. Ćuk,et al.  Orbital evolution of small binary asteroids , 2010 .

[4]  Farquhar,et al.  Estimating the mass of asteroid 253 mathilde from tracking data during the NEAR flyby , 1997, Science.

[5]  Re'em Sari,et al.  TIDAL EVOLUTION OF RUBBLE PILES , 2007, 0712.0446.

[6]  R. Roy,et al.  Photometric Survey of Binary Near-Earth Asteroids , 2006 .

[7]  Petr Pravec,et al.  Binary asteroid population 1. Angular momentum content , 2007 .

[8]  D. Scheeres,et al.  Detailed prediction for the BYORP effect on binary near-Earth Asteroid (66391) 1999 KW4 and implications for the binary population , 2010 .

[9]  W. Crookes V. The Bakerian Lecture.—On the illumination of lines of molecular pressure, and the trajectory of molecules , 1879, Philosophical Transactions of the Royal Society of London.

[10]  A. Love A treatise on the mathematical theory of elasticity , 1892 .

[11]  D. Scheeres,et al.  Secular orbit variation due to solar radiation effects: a detailed model for BYORP , 2009 .

[12]  Joseph A. Burns,et al.  Effects of thermal radiation on the dynamics of binary NEAs , 2004 .

[13]  A. V. Sergeev,et al.  Formation of asteroid pairs by rotational fission , 2010, Nature.

[14]  Daniel J. Scheeres,et al.  Rotational fission of contact binary asteroids , 2007 .

[15]  J. Kawaguchi,et al.  The Rubble-Pile Asteroid Itokawa as Observed by Hayabusa , 2006, Science.

[16]  D. Scheeres,et al.  Dynamics of rotationally fissioned asteroids: Source of observed small asteroid systems , 2011, 1404.0801.

[17]  P. Michel,et al.  Rotational breakup as the origin of small binary asteroids , 2008, Nature.

[18]  Steven Soter,et al.  Q in the solar system , 1966 .

[19]  D. Campbell,et al.  Binary Asteroids in the Near-Earth Object Population , 2002, Science.

[20]  M. Ćuk Formation and Destruction of Small Binary Asteroids , 2007 .

[21]  W. M. Kaula Tidal dissipation by solid friction and the resulting orbital evolution , 1964 .

[22]  T. Gold,et al.  On the Eccentricity of Satellite Orbits in the Solar System , 1963 .