English

BYORP and Dissipation in Binary Asteroids: Lessons from DART

Earth and Planetary Astrophysics 2024-07-01 v1

Abstract

The Near-Earth binary asteroid Didymos was the target of a planetary defense demonstration mission DART in September 2022. The smaller binary component, Dimorphos, was impacted by the spacecraft in order to measure momentum transfer in kinetic impacts into rubble piles. DART and associated Earth-based observation campaigns have provided a wealth of scientific data on the Didymos-Dimorphos binary. DART revealed a largely oblate and ellipsoidal shape of Dimorphos before the impact, while the post-impact observations suggest that Dimorphos now has a prolate shape. Here we add those data points to the known properties of small binary asteroids and propose new paradigms of the radiative binary YORP (BYORP) effect as well as tidal dissipation in small binaries. We find that relatively spheroidal bodies like Dimorphos made of small debris may experience a weaker and more size-dependent BYORP effect than previously thought. This could explain the observed values of period drift in several well-characterized binaries. We also propose that energy dissipation in small binaries is dominated by relatively brief episodes of large-scale movement of (likely surface) materials, rather than long-term steady-state tidal dissipation. We propose that one such episode was triggered on Dimorphos by the DART impact. Depending on the longevity of this high-dissipation regime, it is possible that Dimorphos will be more dynamically relaxed in time for the Hera mission than it was in the weeks following the impact.

Keywords

Cite

@article{arxiv.2406.20064,
  title  = {BYORP and Dissipation in Binary Asteroids: Lessons from DART},
  author = {Matija Ćuk and Harrison Agrusa and Rachel H. Cueva and Fabio Ferrari and Masatoshi Hirabayashi and Seth A. Jacobson and Jay McMahon and Patrick Michel and Paul Sánchez and Daniel J. Scheeres and Stephen Schwartz and Kevin J. Walsh and Yun Zhang},
  journal= {arXiv preprint arXiv:2406.20064},
  year   = {2024}
}

Comments

Accepted for PSJ

R2 v1 2026-06-28T17:22:51.870Z