The JCMT BISTRO-2 Survey: The Magnetic Field in the Center of the Rosette Molecular Cloud

TL;DR

This study presents 850 μm polarization observations of the Rosette Molecular Cloud's active star-forming region, revealing magnetic field structures, grain alignment behavior, and estimates of magnetic field strength and cloud stability.

Contribution

First polarization mapping at 850 μm of the Rosette Molecular Cloud's center, analyzing magnetic field morphology, grain alignment, and magnetic support against gravity.

Findings

Polarization fraction decreases with intensity, indicating partial grain alignment at high densities.

Identified a ring-like structure possibly shaped by feedback, with magnetic fields aligned along its circumference.

Estimated magnetic field strength of 80 μG and a mass-to-flux ratio indicating gravitational collapse is not fully prevented.

Abstract

We present the first 850 $\mu$m polarization observations in the most active star-forming site of the Rosette Molecular Cloud (RMC, $d\sim$1.6 kpc) in the wall of the Rosette Nebula, imaged with the SCUBA-2/POL-2 instruments of the JCMT, as part of the B-Fields In Star-Forming Region Observations 2 (BISTRO-2) survey. From the POL-2 data we find that the polarization fraction decreases with the 850 $\mu$m continuum intensity with $\alpha$ = 0.49 $\pm$ 0.08 in the $p \propto I^{\rm -\alpha}$ relation, which suggests that some fraction of the dust grains remain aligned at high densities. The north of our 850 $\mu$m image reveals a "gemstone ring" morphology, which is a $\sim$1 pc-diameter ring-like structure with extended emission in the "head" to the south-west. We hypothesize that it might have been blown by feedback in its interior, while the B-field is parallel to its circumference in most places. In the south of our SCUBA-2 field the clumps are apparently connected with filaments which follow Infrared Dark Clouds (IRDCs). Here, the POL-2 magnetic field orientations appear bimodal with respect to the large-scale Planck field. The mass of our effective mapped area is $\sim$ 174 $M_\odot$ that we calculate from 850 $\mu$m flux densities. We compare our results with masses from large-scale emission-subtracted Herschel 250 $\mu$m data, and find agreement within 30%. We estimate the POS B-field strength in one typical subregion using the Davis-Chandrasekhar-Fermi (DCF) technique and find 80 $\pm$ 30 $\mu$G toward a clump and its outskirts. The estimated mass-to-flux ratio of $\lambda$ = 2.3 $\pm$ 1.0 suggests that the B-field is not sufficiently strong to prevent gravitational collapse in this subregion.