Magnetic Fields and Velocity Gradients in L1551: The Role of Stellar Feedback

Abstract

Magnetic fields play a crucial role in star formation, yet tracing them becomes particularly challenging, especially in the presence of outflow feedback in protostellar systems. We targeted the star-forming region L1551, notable for its apparent outflows, to investigate the magnetic fields. These fields were probed using polarimetry observations from the Planck satellite at 353 GHZ/849 μm, the SOFIA/HAWC+ measurement at 214 μm, and the JCMT/SCUPOL 850 μm survey. Consistently, all three measurements show that the magnetic fields twist towards the protostar IRS 5. Additionally, we utilized the Velocity Gradients Technique (VGT) on the 12CO (J = 1-0) emission data to distinguish the magnetic fields directly associated with the protostellar outflows. These were then compared with the polarization results. Notably, in the outskirts of the region, these measurements generally align. However, as one approaches the center of IRS 5, the measurements tend to yield mostly perpendicular relative orientations. This suggests that the outflows might be dynamically significant from a scale of approximately 0.2~pc, causing the velocity gradient to change direction by 90 degrees. Furthermore, we discovered that the polarization fraction p and the total intensity I correlate as p I-α. Specifically, α is approximately 1.0440.06 for SCUPOL and around 0.8580.15 for HAWC+. This indicates that the outflows could significantly impact the alignment of dust grains and magnetic fields in the L1551 region.