Resolving the Bright HCN(1-0) Emission toward the Seyfert 2 Nucleus of M51: Shock Enhancement by Radio Jets and Weak Masing by Infrared Pumping?

TL;DR

This study uses high-resolution observations to analyze HCN and CO emissions in M51's nucleus, revealing jet-entrained gas, shock effects, and potential weak masing due to infrared pumping, indicating dense molecular gas near the AGN.

Contribution

First detailed high-resolution analysis of HCN(1-0) emission in M51's nucleus, highlighting jet interactions, shock enhancement, and possible weak masing effects.

Findings

HCN(1-0) distribution aligns with CO, indicating jet-entrained gas.

High HCN/CO brightness ratio (>2) at the nucleus suggests infrared pumping and weak masing.

Presence of dense, obscuring molecular gas near the AGN inferred.

Abstract

We present high angular resolution observations of the HCN(1-0) emission (at ~1" or ~34 pc), together with CO J = 1-0, 2-1, and 3-2 observations, toward the Seyfert 2 nucleus of M51 (NGC 5194). The overall HCN(1-0) distribution and kinematics are very similar to that of the CO lines, which have been indicated as the jet-entrained molecular gas in our past observations. In addition, high HCN(1-0)/CO(1-0) brightness temperature ratio of about unity is observed along the jets, similar to that observed at the shocked molecular gas in our Galaxy. These results strongly indicate that both diffuse and dense gases are entrained by the jets and outflowing from the AGN. The channel map of HCN(1-0) at the systemic velocity shows a strong emission right at the nucleus, where no obvious emission has been detected in the CO lines. The HCN(1-0)/CO(1-0) brightness temperature ratio at this region reaches >2, a value that cannot be explained considering standard physical/chemical conditions. Based on our calculations, we suggest infrared pumping and possibly weak HCN masing, but still requiring an enhanced HCN abundance for the cause of this high ratio. This suggests the presence of a compact dense obscuring molecular gas in front of the nucleus of M51, which remains unresolved at our ~1" (~34 pc) resolution, and consistent with the Seyfert 2 classification picture.