Ionized gas in the starburst core and halo of NGC 1140

TL;DR

This study uses spatially-resolved spectroscopy to analyze ionized gas in NGC 1140, revealing complex kinematics, shock contributions, and turbulent layers driven by starburst activity, with implications for galactic outflow development.

Contribution

It provides detailed kinematic and emission line analysis of NGC 1140's ionized gas, highlighting the role of shocks and turbulence in starburst-driven outflows, a novel insight for irregular galaxies.

Findings

Ionized gas in the galaxy's core is kinematically decoupled from the main body.

No evidence of large-scale galactic outflows was found.

Turbulent mixing layers are responsible for broad emission line components.

Abstract

We present deep WIYN H_alpha SparsePak and DensePak spatially-resolved optical spectroscopy of the dwarf irregular starburst galaxy NGC 1140. The different spatial resolutions and coverage of the two sets of observations have allowed us to investigate the properties and kinematics of the warm ionized gas within both the central regions of the galaxy and the inner halo. We find that the position angle of the H_alpha rotation axis for the main body of the galaxy is consistent with the HI rotation axis at PA = 39 deg, but that the ionized gas in the central 20x20 arcsecs (~2x2 kpc) is kinematically decoupled from the rest of the system, and rotates at a PA approximately perpendicular to that of the main body of the galaxy at +40 deg. We find no evidence of coherent large-scale galactic outflows. Instead multiple narrow emission line components seen within a radius of ~1-1.5 kpc, and high [SII]/H_alpha ratios found beyond ~2 kpc implying a strong contribution from shocks, suggest that the intense star formation is driving material outwards from the main star forming zone in the form of a series of interacting superbubbles/shells. A broad component (100<FWHM<230 km/s) to the H_alpha line is identified throughout galaxy disk out to >2 kpc. Based on recent work, we conclude that it is produced in turbulent mixing layers on the surfaces of cool gas knots embedded within the ISM, set up by the feedback from young massive star clusters. Our data suggest a physical limit to the radius where the broad emission line component is significant, and we propose that this limit marks a significant transition point in the development of the galactic outflow, where turbulent motion becomes less dominant. This mirrors what has recently been found in another similar irregular starburst galaxy NGC 1569.