ALMA Sub-arcsec-resolution 183 GHz H2O and Dense Molecular Line Observations of Nearby Ultraluminous Infrared Galaxies

TL;DR

This study uses high-resolution ALMA observations to analyze dense molecular gas and water emission in nearby ULIRGs, revealing variations in molecular line ratios and the distribution of water emission, with implications for understanding their nuclear regions.

Contribution

First detailed ALMA sub-arcsecond observations of dense molecular lines and water emission in ULIRGs, highlighting differences in molecular ratios and spatial distribution of water emission.

Findings

Higher HCN/HCO+ flux ratios in some AGN-important ULIRGs.

183 GHz H2O emission detected in almost all AGN-important ULIRGs.

H2O emission mainly from entire nuclear regions (~1 kpc).

Abstract

We present the results of ALMA $\sim$2 mm, $\lesssim$1$''$-resolution observations of ten (ultra)luminous infrared galaxies ([U]LIRGs; infrared luminosity $\gtrsim$ 10$^{11.7}$L$_{\odot}$) at $z <$ 0.15, targeting dense ($>$10$^{4}$ cm$^{-3}$) molecular (HCN, HCO$^{+}$, and HNC J=2-1) and 183 GHz H$_{2}$O 3$_{1,3}$-2$_{2,0}$ emission lines. Higher HCN to HCO$^{+}$ J=2-1 flux ratios are observed in some, but not all, AGN-important ULIRGs than in starburst-classified sources. We detect 183 GHz H$_{2}$O emission in almost all AGN-important ULIRGs, and elevated H$_{2}$O emission is found in two sources with elevated HCN J=2-1 emission, relative to HCO$^{+}$ J=2-1. Except one ULIRG (the Superantennae), the H$_{2}$O emission largely comes from the entire nuclear regions ($\sim$1 kpc), rather than AGN-origin megamaser at the very center ($<<$1 kpc). Nuclear ($\sim$1 kpc) dense molecular gas mass derived from HCO$^{+}$ J=2-1 luminosity is $\gtrsim$a few $\times$ 10$^{8}$M$_{\odot}$, and its depletion time is estimated to be $\gtrsim$10$^{6}$ yr in all sources. Vibrationally excited J=2-1 emission lines of HCN and HNC are detected in a few (U)LIRGs, but those of HCO$^{+}$ are not. It is suggested that in mid-infrared-radiation-exposed innermost regions around energy sources, HCO$^{+}$ and HNC are substantially less abundant than HCN. In our ALMA $\sim$2 mm data of ten (U)LIRGs, two continuum sources are serendipitously detected within $\sim$10$''$, which are likely to be an infrared luminous dusty galaxy at $z >$ 1 and a blazar.