Astronomy and Astrophysics – Astronomy
Scientific paper
Feb 1999
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1999apj...511..812g&link_type=abstract
The Astrophysical Journal, Volume 511, Issue 2, pp. 812-821.
Astronomy and Astrophysics
Astronomy
25
Infrared: Ism: Continuum, Ism: Clouds, Ism: Magnetic Fields, Polarization
Scientific paper
We present a nine-point lambda=1.3 mm continuum polarization map of the inner arcminute of the DR 21 cloud core. The polarization and position angles are very uniform, and the inferred magnetic field (P.A.~75^deg) is nearly orthogonal to the cloud elongation (P.A.~7^deg). Applying the virial theorem and comparing the continuum polarimetry, we find that the magnetic field strength must be greater than a few mG to have a significant impact. Turbulent gas motions are probably a more significant source of support against self-gravity in the cloud core than in the magnetic field. We also report a survey of the lambda=1.3 mm polarization of 14 star-forming cloud cores (P =1.6%). The lambda=1.3 mm distribution is similar to the lambda=100 μm and lambda=800 μm polarization distributions in the literature except that the 1.3 mm distribution peaks at P<1%. We compared our polarimetry of nine of the cloud cores to physical parameters derived from far-infrared photometry in a homogeneous fashion. Consistent with theoretical expectations, the polarizations of these cloud cores do not depend on the lambda=1.3 mm dust optical depth, emission temperature, or emissivity spectral index. Although the sample is very small, it appears that the polarization is larger on average for the cloud cores with mean densities of n_H_2>1.5x10^7 cm^-3 than for those with n_H_2<1.5x10^7 cm^-3. The sky-plane projection of the magnetic field lines in the seven elongated cloud cores with 800 μm or 1.3 mm polarization detections greater than 3 sigma appear randomly distributed with respect to the position angles of cloud core elongations. This implies that magnetic fields do not provide substantial anisotropic support against self-gravity in this sample of star-forming cloud cores. The magnetic fields in the cloud cores also appear randomly oriented with respect to the Galactic plane.
Glenn Jason
Walker Christopher K.
Young Erick T.
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