Studying the galactic outflow in NGC 1569

TL;DR

This study uses deep imaging and spectroscopy to analyze the galactic outflow in NGC 1569, revealing ionized filaments, expanding superbubbles, and complex wind-ISM interactions that inform the galaxy's outflow evolution.

Contribution

The paper provides new detailed spatial and kinematic analysis of NGC 1569's outflow, including the detection of ionized filaments and the characterization of wind-ISM interactions.

Findings

Ionized filaments detected in the outer halo.

Superbubbles have expansion velocities of 50-100 km/s.

Broad emission components indicate turbulent wind-ISM interactions.

Abstract

We present deep WIYN H-alpha imaging of the dwarf irregular starburst galaxy NGC 1569, together with WIYN SparsePak spatially-resolved optical spectroscopy of the galactic outflow. This leads on from our previous detailed analyses of the state of the ISM in the central regions of this galaxy. Our deep imaging reveals previously undetected ionized filaments in the outer halo. Through combining these results with our spectroscopy we have been able to re-define the spatial extent of the previously catalogued superbubbles, and derive estimates for their expansion velocities, which we find to be in the range 50-100 km/s. The implied dynamical ages of <25 Myr are consistent with the recent star- and cluster-formation histories of the galaxy. Detailed decomposition of the multi-component H-alpha line has shown that within a distinct region ~700x500 pc in size, roughly centred on the bright super star cluster A, the profile is composed of a bright, narrow (FWHM <= 70 km/s) feature with an underlying, broad component (FWHM ~ 150 km/s). Applying the conclusions found in our previous work regarding the mechanism through which the broad component is produced, we associate the faint, broad emission with the interaction of the hot, fast-flowing winds from the young star clusters with cool clumps of ISM material. This interaction generates turbulent mixing layers on the surface of the clouds and the evaporation and/or ablation of material into the outflow. Under this interpretation, the extent of the broad component region may indicate an important transition point in the outflow, where ordered expansion begins to dominate over turbulent motion. In this context, we present a multi-wavelength discussion of the evolutionary state of the outflow.