Non-principal axis rotation in binary asteroid systems and how it weakens the BYORP effect

Using viscoelastic mass/spring model simulations, we explore tidal evolution and migration of compact binary asteroid systems. We find that after the secondary is captured into a spin-synchronous state, non-principal axis rotation in the secondary can be long-lived. The secondary's long axis can remain approximately aligned along the vector connecting secondary to primary while the secondary rocks back and forth about its long axis. Inward orbital semi-major axis migration can also resonantly excite non-principal axis rotation. By estimating solar radiation forces on triangular surface meshes, we show that the magnitude of the BYORP effect induced torque is sensitive to the secondary's spin state. Non-principal axis rotation within the 1:1 spin-orbit resonance can reduce the BYORP torque or cause frequent reversals in its direction.

Automated summary

In this study, we used viscoelastic mass/spring model simulations to investigate the tidal evolution and migration of compact binary asteroid systems. Our results showed that the non-principal axis rotation in the secondary can be long-lived after it is captured into a spin-synchronous state. Furthermore, the inward orbital semi-major axis migration can resonantly excite non-principal axis rotation.