Probing the magnetic fields and dust properties in the young embedded star-forming region AFGL 6366S using Near Infrared and Optical linear polarimetry

Abstract

We present Near-Infrared (NIR) and Optical linear polarimetry towards the partially embedded cluster AFGL 6366S. The polarization ranges from 0.44-10.3 per cent in NIR and 0.16-11.22 per cent in Optical bands. The position angle spans 1 - 179 in both NIR and Optical bands. About 22 stars exhibit intrinsic polarization signatures. A polarization hole is evident towards the densest ( 3.4 × 1023 cm-2) and warmest ( 28.8 K) central cluster region. It is attributable to depolarization induced by Radiative Torque Disruption (RAT-D) of large grains and a modest contribution from magnetic-field tangling. The local magnetic field towards the cluster's central region is significantly misaligned with both the large-scale Galactic field and the long axis of the filament present in the region. The field morphology wraps around two dense molecular clumps of radii 0.34 pc and 0.22 pc and N( H2) = (7.9 1.1) × 1022 cm-2 and (4.3 0.5) × 1022 cm-2, respectively. The clumps are embedded in the filamentary structure and represent locally accelerated stages of mass accumulation. Gravitationally driven mass flows, largely perpendicular to the local magnetic field, produce a U-shaped field curvature across the filament axis. The plane-of-sky magnetic field strengths towards the two clumps are 447.91 83.81 μG and 396.66 73.64 μG. The corresponding mass-to-flux ratios (λ 1.34 and 0.82) indicate that one clump is magnetically supercritical and the other is subcritical. The Alfven Mach numbers (MA) 0.395 and 0.393 indicate that both the clumps are in sub-Alfv\'enic state.