A multi-wavelength exploration of the [CII]/IR ratio in H-ATLAS/GAMA galaxies out to z=0.2

TL;DR

This study investigates the [CII]/IR ratio in a sample of nearby galaxies, revealing how galaxy properties and UV radiation influence the [CII] deficit at high IR luminosities, using Herschel observations.

Contribution

It provides new insights into the physical drivers of the [CII] deficit, linking UV radiation fields and galaxy morphology to the [CII]/IR ratio in local galaxies.

Findings

High [CII]/IR ratios are associated with lower IR luminosity and colder dust.

Galaxies with high ratios tend to have disk-like morphology and low surface brightness.

The strength of UV radiation fields is a key factor affecting the [CII]/IR ratio.

Abstract

We explore the behaviour of [CII]-157.74um forbidden fine-structure line observed in a sample of 28 galaxies selected from ~50deg^2 of the H-ATLAS survey. The sample is restricted to galaxies with flux densities higher than S_160um>150mJy and optical spectra from the GAMA survey at 0.02<z<0.2. Far-IR spectra centred on this redshifted line were taken with the PACS instrument on-board the Herschel Space Observatory. The galaxies span 10<log(L_IR/Lo)<12 (where L_IR=L_IR[8-1000um]) and 7.3<log(L_[CII]/Lo)<9.3, covering a variety of optical galaxy morphologies. The sample exhibits the so-called [CII] deficit at high IR luminosities, i.e. L_[CII]/L_IR (hereafter [CII]/IR) decreases at high L_IR. We find significant differences between those galaxies presenting [CII]/IR>2.5x10^-3 with respect to those showing lower ratios. In particular, those with high ratios tend to have: (1) L_IR<10^11Lo; (2) cold dust temperatures, T_d<30K; (3) disk-like morphologies in r-band images; (4) a WISE colour 0.5<S_12um/S_22um<1.0; (5) low surface brightness Sigma_IR~10^8-9 Lo kpc^-2, (6) and specific star-formation rates of sSFR~0.05-3 Gyr^-1. We suggest that the strength of the far-UV radiation fields (<G_O>) is main parameter responsible for controlling the [CII]/IR ratio. It is possible that relatively high <G_O> creates a positively charged dust grain distribution, impeding an efficient photo-electric extraction of electrons from these grains to then collisionally excite carbon atoms. Within the brighter IR population, 11<log(L_IR/Lo)<12, the low [CII]/IR ratio is unlikely to be modified by [CII] self absorption or controlled by the presence of a moderately luminous AGN (identified via the BPT diagram).