Kinematics of the Atomic ISM in M33 on 80 pc scales

TL;DR

This study uses high-resolution radio observations to analyze the complex kinematics of atomic hydrogen in M33, revealing non-Gaussian profiles, radial trends in line width, and large HI structures.

Contribution

It provides detailed measurements of HI line widths and profiles in M33 at 80 pc resolution, highlighting spectral complexity and large-scale HI features.

Findings

HI line width decreases slightly with radius

Spectral profiles often show non-Gaussian features

Large HI clouds and filaments are detected far from the galaxy's rotation axis

Abstract

We present new L-band ($1\mbox{--}2$ GHz) observations of the nearby spiral galaxy M33 with 80 pc resolution obtained with the Karl G. Jansky Very Large Array. The HI observations, combined with HI measurements from the Green Bank Telescope, improve the spectral resolution and sensitivity ($2.8$ K rms noise in a $0.2$ km s$^{-1}$ channel) compared to previous observations. We find individual profiles are usually non-Gaussian, harbouring line wings, multiple components, and asymmetries. Given this spectral complexity, we quantify the motions in the atomic ISM through moment analysis of the spectra and fits to aligned, stacked profiles. The measured value of the HI line width depends strongly on the method used, with the velocity stacked profiles aligned to the peak velocity giving the minimum value of $\sigma = 7$ km s$^{-1}$ and all other methods giving higher values ($\sigma\sim10$ km s$^{-1}$). All measurements of the line width show a shallow radial trend, with $\sigma$ decreasing by $\sim2$ km s$^{-1}$ from $R_{\rm gal}=0$ to $R_{\rm gal}=8$ kpc. We consider a number of energy sources that might maintain the line width against turbulent dissipation, but no single source is adequate. We find excess emission relative to a Gaussian in the stacked profile line wings, ranging from 9% to 26% depending on how the spectra are aligned. By splitting the line wings into symmetric and asymmetric components, we find that the lagging rotational disk accounts for one-third of the line wing flux. We also find emission far from the rotation axis of the galaxy in multiple discrete HI clouds, including a filament with a projected length of $\sim8$ kpc.