Cyano radical emission at small spatial scales towards massive protostars

TL;DR

This study uses high-resolution ALMA observations to analyze the spatial distribution of CN emission in massive protostars, revealing its presence in various star formation stages and its potential role in astrochemical processes.

Contribution

It provides the first high-angular resolution analysis of CN emission at small scales in massive star-forming regions, linking molecular distribution to star formation stages.

Findings

CN traces both condensations and diffuse gas.

CN emission peaks do not always coincide with continuum peaks.

CN is present across different evolutionary stages.

Abstract

The cyano radical (CN), one of the first detected interstellar molecular species, is a key molecule in many astrochemical chains. Particularly, it is detected towards molecular cores, the birth places of the stars, and it is known that it is involved in the rich chemistry that takes place in these sites. At present there are not so many studies about the emission of this molecular species at small spatial scales towards massive young stellar objects. Thus, we present a high-angular resolution CN study towards a sample of massive protostars, with the aim of unveiling the spatial distribution at the small scale of the emission of this radical in relation to the star-forming processes. The interstellar CN has a strong emission line at the rest frequency 226874.764 MHz, thus, we search for observing projects in the ALMA database regarding high-mass star-forming regions observed at Band 6. A sample of ten high-mass star-forming regions were selected in base on that they present a clear emission of CN at the mentioned frequency. We found that the CN traces both molecular condensations and diffuse and extended gas surrounding them. In general, the molecular condensations traced by the maximums of the CN emission do not spatially coincide with the peaks of the continuum emission at 1.3 mm, which trace the molecular cores where the massive stars born. Based on the presence or lack of near-IR emission associated with such cores, we suggest that our sample is composed by sources at different stages of evolution. The CN is present at both, suggesting that this radical may be ubiquitous along the different star formation stages, and hence it may be involved in different chemical reactions occurring along the time in the formation of the stars. Additionally, other complex molecules were detected towards the continuum peaks of some of the analyzed cores.