Aromatic rings in the Central Molecular Zone: Benzonitrile

TL;DR

This study reports the detection of benzonitrile in warmer molecular clouds of the Central Molecular Zone, revealing its widespread presence and suggesting aromatic molecules' stability and contribution to interstellar carbon in diverse environments.

Contribution

First detection of benzonitrile in the CMZ's warmer clouds, expanding understanding of aromatic molecules' survival and chemistry in harsher interstellar environments.

Findings

Benzonitrile detected with specific column densities and abundances in two CMZ clouds.

The HC7N/benzonitrile ratio is lower in CMZ than in colder sources, indicating environmental effects.

Benzonitrile's abundance suggests aromatic molecules are stable and contribute significantly to interstellar carbon.

Abstract

In recent years, several aromatic molecules (benzene-based rings) have been detected in the cold molecular cloud TMC-1, with its CN-derivative, benzonitrile (c-C$_6$H$_5$CN), also identified in other nearby cold sources. However, observed abundances differ significantly from chemical model predictions, indicating an incomplete understanding of its chemistry and motivating searches in distinct environments. We report new detections of benzonitrile in two warmer molecular clouds of the Central Molecular Zone (CMZ): G+0.693-0.027 and G+0.633-0.0604. Using Yebes 40m ultra-deep surveys in the 31--50 GHz range, we performed LTE and non-LTE analyses to derive the physical parameters of the emission. We obtain column densities of $N$=(7.4$\pm$0.5)$\times10^{12}$ and (2.60$\pm$0.13)$\times10^{12}$ cm$^{-2}$, corresponding to abundances relative to H$_2$ of (6$\pm$1)$\times10^{-11}$ and (4.3$\pm$0.9)$\times10^{-11}$, consistent with values in cold Galactic clouds. The HC$_7$N/benzonitrile ratio is lower (2.15-2.4) than in colder sources (4.5-30), suggesting environmental effects and a relative enhancement of aromatic chemistry in the CMZ. These results confirm that benzonitrile is widespread and can survive in harsher environments (e.g., high temperatures, shocks, enhanced cosmic-ray ionization) than those in Galactic cold clouds. This suggests that aromatics are stable and abundant species that can significantly contribute to the total budget of interstellar carbon in molecular clouds. A top-down formation scenario, involving fragmentation of larger carbonaceous species, is consistent with the nearly constant abundances observed with molecular size.