The Importance of the Magnetic Field from an SMA-CSO-Combined Sample of Star-Forming Regions

Abstract

Submillimeter dust polarization measurements of a sample of 50 star-forming regions, observed with the SMA and the CSO covering pc-scale clouds to mpc-scale cores, are analyzed in order to quantify the magnetic field importance. The magnetic field misalignment δ -- the local angle between magnetic field and dust emission gradient -- is found to be a prime observable, revealing distinct distributions for sources where the magnetic field is preferentially aligned with or perpendicular to the source minor axis. Source-averaged misalignment angles |δ| fall into systematically different ranges, reflecting the different source-magnetic field configurations. Possible bimodal |δ|-distributions are found for the separate SMA and CSO samples. Combining both samples broadens the distribution with a wide maximum peak at small |δ|-values. Assuming the 50 sources to be representative, the prevailing source-magnetic field configuration is one that statistically prefers small magnetic field misalignments |δ|. When interpreting |δ| together with an MHD force equation, as developed in the framework of the polarization-intensity gradient method, a sample-based scaling fits the magnetic field tension-to-gravity force ratio B versus |δ| with B = 0.116 · (0.047· |δ|) 0.20 (mean error), providing a way to estimate the relative importance of the magnetic field, only based on measurable field misalignments |δ|. The force ratio B discriminates systems that are collapsible on average ( B <1) from other molecular clouds where the magnetic field still provides enough resistance against gravitational collapse ( B >1) (abridged).