Variations of the Mid-IR Aromatic Features Inside and Among Galaxies

TL;DR

This study analyzes mid-infrared spectra from various galactic regions and galaxies, revealing that PAH feature ratios are mainly influenced by PAH ionization levels, providing a diagnostic tool for physical conditions.

Contribution

It demonstrates the universality of PAH properties across different environments and establishes an empirical relation linking PAH ratios to physical parameters.

Findings

PAH band ratios are consistent within and among galaxies.

Variations in ratios are primarily due to PAH ionization, not size or extinction.

Provides a diagnostic relation for physical conditions based on PAH ratios.

Abstract

We present the results of a systematic study of mid-IR spectra of Galactic regions, Magellanic HII regions, and galaxies of various types (dwarf, spiral, starburst), observed by the satellites ISO and Spitzer. We study the relative variations of the 6.2, 7.7, 8.6 and 11.3 micron features inside spatially resolved objects (such as M82, M51, 30 Doradus, M17 and the Orion Bar), as well as among 90 integrated spectra of 50 objects. Our main results are that the 6.2, 7.7 and 8.6 micron bands are essentially tied together, while the ratios between these bands and the 11.3 micron band varies by one order of magnitude. This implies that the properties of the PAHs are remarkably universal throughout our sample, and that the relative variations of the band ratios are mainly controled by the fraction of ionized PAHs. In particular, we show that we can rule out both the modification of the PAH size distribution, and the mid-infrared extinction, as an explanation of these variations. Using a few well-studied Galactic regions (including the spectral image of the Orion Bar), we give an empirical relation between the I(6.2)/I(11.3) ratio and the ionization/recombination ratio G0/ne.Tgas^0.5, therefore providing a useful quantitative diagnostic tool of the physical conditions in the regions where the PAH emission originates. Finally, we discuss the physical interpretation of the I(6.2)/I(11.3) ratio, on galactic size scales.