Magnetically regulated disk-formation in the inner 100 au region of the Class 0 young stellar object OMC-3/MMS~6 resolved by JVLA and ALMA

Abstract

We have carried out polarization calibration for archival JVLA (9 mm) full polarization observations towards the Class 0 young stellar object (YSO) OMC-3/MMS 6 (also known as HOPS-87), and then compared with the archival ALMA 1.2 mm observations. We found that the innermost 100 au region of OMC-3/MMS 6 is likely very optically thick (e.g., τ1) at 1 mm wavelength such that the dominant polarization mechanism is dichroic extinction. It is marginally optically thin (e.g., τ1) at 9 mm wavelength such that the JVLA observations can directly probe the linearly polarized emission from non-spherical dust. Assuming that the projected long axis of dust grains is aligned perpendicular to magnetic field (B-field) lines, we propose that the overall B-field topology resembles an hourglass shape, while this "hourglass" appears 40 inclined with respect to the previously reported outflow axis. The geometry of this system is consistent with a magnetically regulated dense (pseudo-)disk. Based on the observed 29.45 GHz flux density and assuming a dust absorption opacity abs29.45\,GHz=0.0096 cm2 g-1, the derived overall dust mass within a 43 au radius is 14000 M. From this case study, it appears to us that some previous 9 mm surveys towards Class 0/I YSOs might have systematically underestimated dust masses by one order of magnitude, owing to that they assumed the too high dust absorption opacity (0.1 cm2 g-1) for 9 mm wavelengths but without self-consistently considering the dust scattering opacity.