Submillimeter-HCN Diagram for an Energy Diagnostics in the Centers of Galaxies

TL;DR

This study uses submillimeter molecular line ratios to diagnose energy sources in galaxy centers, finding enhanced HCN ratios in AGNs likely due to chemical abundance differences rather than density effects.

Contribution

It provides an expanded galaxy sample and suggests chemical abundance variations as the main cause of high HCN line ratios in AGNs, challenging conventional XDR models.

Findings

Enhanced HCN/HCO$^+$ and HCN/CS ratios observed in AGNs

High line ratios likely due to increased HCN abundance in AGNs

Conventional XDR models insufficient to explain observations

Abstract

Compiling data from literature and the ALMA archive, we show enhanced HCN(4-3)/HCO$^+$(4-3) and/or HCN(4-3)/CS(7-6) integrated intensity ratios in circumnuclear molecular gas around active galactic nuclei (AGNs) compared to those in starburst (SB) galaxies (submillimeter HCN-enhancement). The number of sample galaxies is significantly increased from our previous work. We expect this feature could potentially be an extinction-free energy diagnostic tool of nuclear regions of galaxies. Non-LTE radiative transfer modelings of the above molecular emission lines involving both collisional and radiative excitation, as well as a photon trapping effect were conducted to investigate the cause of the high line ratios in AGNs. As a result, we found that enhanced abundance ratios of HCN-to-HCO$^+$ and HCN-to-CS in AGNs as compared to SB galaxies by a factor of a few to even $>$ 10 is a plausible explanation for the submillimeter HCN-enhancement. However, a counter argument of a systematically higher gas density in AGNs than in SB galaxies can also be a plausible scenario. Although we could not fully discriminate these two scenarios at this moment due to insufficient amount of multi-transition, multi-species data, the former scenario equivalently claims for abnormal chemical composition in AGNs. Regarding the actual mechanism to realize the composition, we suggest it is difficult with conventional gas phase X-ray dominated region (XDR) ionization models to reproduce the observed high line ratios. We might have to take into account other mechanisms such as neutral-neutral reactions that are efficiently activated at high temperature environments and/or mechanically heated regions to further understand the high line ratios in AGNs.