Core orientations and magnetic fields in isolated molecular clouds

TL;DR

This study investigates the alignment of magnetic fields in molecular clouds and their relation to cloud morphology, finding general alignment at larger scales but random core orientations, with implications for cloud magnetization and star formation.

Contribution

The paper provides new observational evidence linking magnetic field orientations across different scales in molecular clouds and assesses their role in cloud stability and morphology.

Findings

Magnetic fields from optical and Planck data agree and align with cloud emission.

Core orientations are randomly distributed relative to magnetic fields.

Most clouds are magnetically critical, with some envelope support by magnetic fields.

Abstract

Molecular clouds are sites of star formation. Magnetic fields are believed to play an important role in their dynamics and shaping morphology. We aim to study any possible correlation that might exist between the magnetic fields orientation inside the clouds and the magnetic fields at envelope scales and their connection with respect to the observed morphology of the selected clouds. We examine the magnetic field orientation towards the clouds L1512, L1523, L1333, L1521E, L1544, L1517, L1780, and L183 using optical and \textit{Planck} polarization observations. We also found the correlation between the ambient magnetic field and core orientations derived using \textit{Astrodendrogram} on the \textit{Herschel} 250 $\mu$m data. We find that the magnetic fields derived from optical and \textit{Planck} agree with each other. The derived magnetic fields are aligned along the observed emission of each cloud as seen in \textit{Herschel} 250 $\mu$m data. We also find that the relative orientation between the cores and the magnetic fields is random. This lack of correlation may arise due to the fact that the core orientation could also be influenced by the different magnetization within individual clouds at higher densities or the feedback effects which may vary from cloud to cloud. The estimated magnetic field strength and the mass-to-flux ratio suggest that all the clouds are in a magnetically critical state except L1333, L1521E, and L183 where the cloud envelope could be strongly supported by the magnetic field lines.