Exploring Hydrodynamic Instabilities along the Infalling High-Velocity Cloud Complex A

Abstract

Complex A is a high-velocity cloud that is traversing through the Galactic halo toward the Milky Way's disk. We combine both new and archival Green Bank Telescope observations to construct a spectroscopically resolved HI~21-cm map of this entire complex at a 17.1(N HI,\,1σ/ cm-2)17.9 sensitivity for a FWHM=20~ km\, s-1 line and θ=9.1\, arcmins or 17 dθ30~ pc spatial resolution. We find that that Complex A is has a Galactic standard of rest frame velocity gradient of vGSR/ L=25~ km\, s-1/ kpc along its length, that it is decelerating at a rate of a GSR=55~ km/ yr2, and that it will reach the Galactic plane in t70~ Myrs if it can survive the journey. We have identify numerous signatures of gas disruption. The elongated and multi-core structure of Complex A indicates that either thermodynamic instabilities or shock-cascade processes have fragmented this stream. We find Rayleigh-Taylor fingers on the low-latitude edge of this HVC; many have been pushed backward by ram-pressure stripping. On the high-latitude side of the complex, Kelvin-Helmholtz instabilities have generated two large wings that extend tangentially off Complex A. The tips of these wings curve slightly forward in the direction of motion and have an elevated \ column density, indicating that these wings are forming Rayleigh-Taylor globules at their tips and that this gas is becoming entangled with unseen vortices in the surrounding coronal gas. These observations provide new insights on the survivability of low-metallicity gas streams that are accreting onto L galaxies.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…