Initial velocity V-shapes of young asteroid families

TL;DR

This study uses the V-shape identification technique to analyze young asteroid families under 20 million years old, aiming to constrain their initial ejection velocity fields before Yarkovsky effect dispersal dominates.

Contribution

It applies the V-shape method to measure the curvature of 11 young asteroid families, providing new constraints on their initial velocity fields and confirming the inverse diameter scaling.

Findings

Most families have initial ejection velocities consistent with D^{-1} scaling.

Supports laboratory and simulation results of asteroid disruption.

Provides the first systematic measurement of initial velocity fields for multiple young families.

Abstract

Ejection velocity fields of asteroid families are largely unconstrained due to the fact that members disperse relatively quickly on Myr time-scales by secular resonances and the Yarkovsky effect. The spreading of fragments in $a$ by the Yarkovsky effect is indistinguishable from the spreading caused by the initial ejection of fragments. By examining families $<$20 Myrs-old, we can use the V-shape identification technique to separate family shapes that are due to the initial ejection velocity field and those that are due to the Yarkovsky effect. $<$20 Myr-old asteroid families provide an opportunity to study the velocity field of family fragments before they become too dispersed. Only the Karin family's initial velocity field has been determined and scales inversely with diameter, $D^{-1}$. We have applied the V-shape identification technique to constrain young families' initial ejection velocity fields by measuring the curvature of their fragments' V-shape correlation in semi-major axis, $a$, vs. $D^{-1}$ space. Curvature from a straight line implies a deviation from a scaling of $D^{-1}$. We measure the V-shape curvature of 11 young asteroid families including the \FYnospace, Aeolia, Brangane, Brasilia, Clarissa, Iannini, Karin, Konig, Koronis(2), Theobalda and Veritas asteroid families. We find that the majority of asteroid families have initial ejection velocity fields consistent with $\sim D^{-1}$ supporting laboratory impact experiments and computer simulations of disrupting asteroid parent bodies.