NGC 1266: Characterization of the Nuclear Molecular Gas in an Unusual SB0 Galaxy

TL;DR

This study characterizes the nuclear molecular gas in the unusual SB0 galaxy NGC 1266, revealing distinct temperature and mass components in the nuclear and outflow regions, with evidence of shock excitation.

Contribution

It provides a detailed analysis of the molecular gas properties in NGC 1266 using new Herschel observations, decomposing nuclear and outflow components and exploring their excitation mechanisms.

Findings

Nuclear and outflow gas are predominantly cool, with warm components contributing most to luminosity.

The outflow exhibits an unusually high CO to FIR luminosity ratio, indicating shock excitation.

Mass and luminosity distributions differ significantly between nuclear and outflow gas.

Abstract

With a substantial nuclear molecular gas reservoir and broad, high-velocity CO molecular line wings previously interpreted as an outflow, NGC 1266 is a rare SB$0$ galaxy. Previous analyses of interferometry, spectrally resolved low-$J$ CO emission lines, and unresolved high-$J$ emission lines have established basic properties of the molecular gas and the likely presence of an AGN. Here, new spectrally resolved CO $J = 5 - 4$ to $J = 8 - 7$ lines from {\it Herschel Space Observatory} HIFI observations are combined with ground-based observations and high-$J$ {\it Herschel} SPIRE observations to decompose the nuclear and putative outflow velocity components and to model the molecular gas to quantify its properties. Details of the modeling and results are described, with comparisons to previous results and exploration of the implications for the gas excitation mechanisms. Among the findings, like for other galaxies, the nuclear and putative outflow molecular gas are well represented by components that are cool ($T_{nuclear} = 6^{+10}_{-2}$ K and $T_{outflow} \sim 30$ K), comprising bulk of the mass (Log $M_{nuclear}/M_{\odot} = 8.3^{+0.5}_{-0.4}$ and Log $M_{outflow}/M_{\odot} = 7.6^{+0.3}_{-0.3}$), and the minority of the luminosity (Log $L_{nuclear}/L_{\odot} = 5.44^{+0.22}_{-0.18}$ and Log $L_{outflow}/L_{\odot} \sim 6.5$) and warm ($T_{nuclear} = 74^{+130}_{-26}$ K and $T_{outflow} > 100$ K), comprising a minority of the mass (Log $M_{nuclear}/M_{\odot} = 7.3^{+0.5}_{-0.5}$ and Log $M_{outflow}/M_{\odot} \sim 6.3$) but the majority of the luminosity (Log $L_{nuclear}/L_{\odot} = 6.90^{+0.16}_{-0.16}$ and Log $L_{outflow}/L_{\odot} \sim 7.2$). The outflow has an anomalously high $L_\mathrm{CO}/L_\mathrm{FIR}$ of $1.7 \times 10^{-3}$ and is almost certainly shock excited.