SIMBAD references

Magnetic fields have only recently been included in theoretical simulations of high-mass star formation. The simulations show that magnetic fields play an important role in the formation and dynamics of molecular outflows. Masers, in particular 6.7-GHz CH₃OH masers, are the best probes of the magnetic field morphologies around massive young stellar objects on the smallest scales of 10-100AU. Providing new observational measurements of the morphology of magnetic fields around massive young stellar objects by using 6.7-GHz CH₃OH maser emission is very important for setting constraints on the numerical simulations of massive star formation. This paper focuses on 4 massive young stellar objects, IRAS06058+2138-NIRS 1, IRAS22272+6358A, S255-IR, and S231, which complement our previous 2012 sample (the first EVN group). From all these sources, molecular outflows have been detected in the past. Seven of the European VLBI Network antennas were used to measure the linear polarization and Zeeman-splitting of the 6.7-GHz CH₃OH masers in the star-forming regions in this second EVN group. We detected a total of 128 CH₃OH masing cloudlets. Fractional linear polarization (0.8%-11.3%) was detected towards 18% of the CH₃OH masers in our sample. The linear polarization vectors are well ordered in all the massive young stellar objects. We measured significant Zeeman-splitting in IRAS06058+2138-NIRS 1 (ΔV_Z=3.8±0.6m/s) and S255-IR (ΔV_Z=3.2±0.7m/s). By considering the 20 massive young stellar objects towards which the morphology of magnetic fields was determined by observing 6.7-GHz CH₃OH masers in both hemispheres, we find no evident correlation between the linear distributions of CH₃OH masers and the outflows or the linear polarization vectors. On the other hand, we present first statistical evidence that the magnetic field (on scales 10-100AU) is primarily oriented along the large-scale outflow direction. Moreover, we empirically find that the linear polarization fraction of unsaturated CH₃OH masers is P_l<4.5%.