Multiwavelength Vertical Structure in the AU Mic Debris Disk: Characterizing the Collisional Cascade

TL;DR

This study uses high-resolution ALMA observations to analyze the vertical structure and grain size distribution in the AU Mic debris disk, testing the collisional cascade model and revealing unexpected collision dynamics.

Contribution

It provides the first detailed measurements of the disk's aspect ratio at multiple wavelengths and derives a velocity dispersion size dependence, challenging existing assumptions about small body strength.

Findings

Smaller bodies are more easily disrupted than larger ones.

The velocity dispersion size index p is approximately 0.28.

The aspect ratio varies between 0.019 and 0.025 at different wavelengths.

Abstract

Debris disks are scaled-up analogs of the Kuiper Belt in which dust is generated by collisions between planetesimals. In the "collisional cascade" model of debris disks, dust lost to radiation pressure and winds is constantly replenished by grinding collisions between planetesimals. The model assumes that collisions are destructive and involve large velocities; this assumption has not been tested beyond our Solar System. We present 0"25 ($\approx$2.4 au) resolution observations of the $\lambda$ = 450 $\mu$m dust continuum emission from the debris disk around the nearby M dwarf AU Microscopii with the Atacama Large Millimeter/submillimeter Array. We use parametric models to describe the disk structure, and an MCMC algorithm to explore the posterior distributions of the model parameters; we fit the structure of the disk to both our data and archival $\lambda = 1.3$ mm data (Daley et al. 2019), from which we obtain two aspect ratio measurements at 1.3 mm ($h_{1300}$ = 0.025$^{+0.008}_{-0.002}$) and at 450 $\mu$m ($h_{450}$ = 0.019$^{+0.006}_{-0.001}$), as well as the grain size distribution index $q =$ 3.03 $\pm$ 0.02. Contextualizing our aspect ratio measurements within the modeling framework laid out in Pan & Schlichting (2012), we derive a power law index of velocity dispersion as a function of grain size $p = 0.28 \pm 0.06$ for the AU Mic debris disk. This result implies that smaller bodies are more easily disrupted than larger bodies by collisions, which is inconsistent with the strength regime usually assumed for such small bodies. Possible explanations for this discrepancy are discussed.