Infrared Spectroscopy of Halos of Edge-on Galaxies

TL;DR

This study uses infrared spectroscopy to analyze ionized gas, PAHs, and molecular hydrogen in the halos of edge-on galaxies, revealing increased radiation hardness and extended molecular and PAH layers with height.

Contribution

It provides new insights into the vertical distribution and physical conditions of gas and dust in galaxy halos using Spitzer spectra and modeling.

Findings

Radiation hardness increases with height in galaxy halos.

PAHs and molecular hydrogen have large scale heights, indicating extended halo layers.

PAH features are more prominent in halos, suggesting transport by disk-halo flows.

Abstract

We present a study of ionized gas, PAHs, and molecular hydrogen emission in the halos of three edge-on galaxies, NGC 891, NGC 5775 and NGC 3044, based on 10-20 micron Spitzer Space Telescope spectra. The [Ne III]/[Ne II] ratio, an excellent measure of radiation hardness, rises with z in the halo of NGC 891. It is also higher in the halo of NGC 5775 than in the disk. NGC 3044 presents a more confusing situation. To explain the [Ne III]/[Ne II] as well as optical line ratio behavior in NGC 891, we carry out a simple exploration of parameter space with CLOUDY, which indicates a large increase in radiation temperature with height. Illustrative examples of physical models using a Monte Carlo radiative transfer code show that the rising neon ratio may be explained by adding a vertically extended, hot stellar source to a thin disk of massive stars. However, several other sources of hard spectra may be relevant. PAH features have scale heights of 430--530 pc in NGC 891 and 720--1080 pc in NGC 5775, suggesting they can be transported by disk-halo flows. Within NGC 891 and NGC 5775, scale heights are similar for all PAHs. For NGC 891, the scale heights exceed that of 8 micron emission, indicating a transition from more ionized to more neutral PAHs with height. Most PAH equivalent widths are higher in the halos. Molecular hydrogen 17.03 micron emission with scale heights of 550-580 pc in NGC 891 and 850 pc in NGC 5775 suggests a molecular component in a surprisingly thick layer.