Molecular shock tracers in NGC 1068: SiO and HNCO

TL;DR

This study investigates the distribution and origin of SiO and HNCO emissions in NGC 1068, revealing different shock conditions and chemical processes in the galaxy's core regions through imaging, LTE, RADEX, and chemical modeling.

Contribution

It provides a detailed analysis of shock tracers SiO and HNCO in NGC 1068, linking their emission patterns to shock velocities and gas conditions, which is novel in understanding galaxy core chemistry.

Findings

SiO peaks east of the AGN, indicating fast shocks.

HNCO is more prominent west, suggesting slow shocks or warm non-shocked gas.

East region likely contains heavily shocked gas, while the West may be non-shocked or mildly shocked.

Abstract

SiO(3-2) and HNCO(6-5) emission has been imaged in NGC 1068 with the Plateau de Bure Interferometer (PdBI). We perform an LTE and RADEX analysis to determine the column densities and physical characteristics of the gas emitting these two lines. We then use a chemical model to determine the origin of the emission. There is a strong SiO peak to the East of the AGN, with weak detections to the West. This distribution contrasts that of HNCO, which is detected more strongly to the West. The SiO emission peak in the East is similar to the peak of the molecular gas mass traced by CO. HNCO emission is offset from this peak by as much as 80 pc ( 1"). We compare velocity integrated line ratios in the East and West. We confirm that SiO emission strongly dominates in the East, while the reverse is true in the West. We use RADEX to analyse the possible gas conditions that could produce such emission. We find that, in both East and West, we cannot constrain a single temperature for the gas. We run a grid of chemical models of potential shock processes in the CND and find that SiO is significantly enhanced during a fast (60 km/s) shock but not during a slow (20 km/s) shock, nor in a gas not subjected to shocks at all. We find the inverse for HNCO, whose abundance increases during slow shocks and in warm non-shocked gas. High SiO and low HNCO indicated a fast shock, while high HNCO and low SiO indicates either a slow shock or warm, dense, non-shocked gas. The East Knot is therefore likely to contain gas that is heavily shocked. From chemical modelling, gas in the West Knot may be non-shocked, or maybe undergoing a much milder shock event. When taking into account RADEX results, the milder shock event is the more likely of the two scenarios.