A holistic perspective on the dynamics of G035.39-00.33: the interplay between gas and magnetic fields

Magnetic fields are one of the key agents playing a crucial role in shaping the formation of massive molecular clouds and star formation, yet the complete information on B-fields is not well constrained due to the limitations in the observations. We study the magnetic fields in the massive infrared dark cloud G035.39-00.33 from dust continuum polarization observations at 850 $\micron$ with the SCUBA-2/POL-2 instrument at the JCMT. A network of filaments covering a broad range of densities is revealed in the sensitive SCUBA-2/POL-2 observations. The magnetic field tends to be perpendicular to the densest (with N(H$_{2})>7\times10^{21}$ cm$^{-2}$) middle part of the most massive filament (F$_{M}$), whereas it tends to be parallel in less dense filaments and other locations of F$_{M}$. F$_{M}$ seems to be formed due to large-scale ($\sim$10 pc) cloud-cloud collision as evident from $^{13}$CO (1-0) line observations. A mean plane-of-sky magnetic field strength of $\sim$50 $\mu$G for F$_{M}$ is obtained with Davis-Chandrasekhar-Fermi method. F$_{M}$ is gravitationally unstable if it is supported only by thermal pressure and turbulence. The northern part of F$_{M}$, however, can be stable given modest additional support from the local magnetic field. The middle and southern parts of F$_{M}$ are likely unstable even if magnetic field support is taken into account. Nine clumps with a nearly even spacing ($\sim$0.9 pc) are identified along F$_{M}$. The magnetic field plays a role as important as turbulence in supporting those clumps against gravitational collapse. Finally, we identified for the first time a massive ($\sim$200 M$_{\sun}$), collapsing starless clump candidate, "c8". The magnetic field surrounding "c8" is likely pinched, hinting at an accretion flow along the filament.