Stellar Winds and Dust Avalanches in the AU Mic Debris Disk

TL;DR

This paper models the fast-moving dust features in the AU Mic debris disk as avalanches triggered by collisions at ring intersections, driven by stellar wind and magnetic effects, explaining observed dynamics and structures.

Contribution

It introduces a quantitative model of dust avalanches caused by ring interactions and stellar wind, explaining the observed features in the AU Mic debris disk.

Findings

Reproduces masses, sizes, and velocities of dust clouds.

Identifies the intersection of debris rings as avalanche zones.

Suggests magnetic field reversals cause vertical undulations.

Abstract

We explain the fast-moving, ripple-like features in the edge-on debris disk orbiting the young M dwarf AU Mic. The bright features are clouds of sub-micron dust repelled by the host star's wind. The clouds are produced by avalanches: radial outflows of dust that gain exponentially more mass as they shatter background disk particles in collisional chain reactions. The avalanches are triggered from a region a few AU across -- the "avalanche zone" -- located on AU Mic's primary "birth" ring, at a true distance of $\sim$35 AU from the star but at a projected distance more than a factor of 10 smaller: the avalanche zone sits directly along the line of sight to the star, on the side of the ring nearest Earth, launching clouds that disk rotation sends wholly to the southeast, as observed. The avalanche zone marks where the primary ring intersects a secondary ring of debris left by the catastrophic disruption of a progenitor up to Varuna in size, less than tens of thousands of years ago. Only where the rings intersect are particle collisions sufficiently violent to spawn the sub-micron dust needed to seed the avalanches. We show that this picture works quantitatively, reproducing the masses, sizes, and velocities of the observed escaping clouds. The Lorentz force exerted by the wind's magnetic field, whose polarity reverses periodically according to the stellar magnetic cycle, promises to explain the observed vertical undulations. The timescale between avalanches, about 10 yr, might be set by time variability of the wind mass-loss rate or, more speculatively, by some self-regulating limit cycle.