B-Fields and Star Formation across Scales with TRAO (B-FROST): CO Abundances, Dynamics and Relative Orientations in the Translucent High Latitude Cloud MBM12

Abstract

In our Galaxy, the average star formation efficiency is of the order of a few percent. We investigated the high-latitude molecular cloud MBM12 as part of the B-fields and star formation across scales (B-FROST) survey with the Taeduk Radio Astronomical Observatory (TRAO) to assess why star formation activity in MBM12 is low. We combine Herschel-based, locally κν-calibrated N(H2) estimates with 12CO and 13CO (J=1-0) observations (2.5 ×3 at 48'') to map N(CO), X(CO), and [CO/H2], compute multi-scale α vir and mass-size scaling laws from dendrograms, and derive the histogram of relative orientations from Planck dust polarisation. We identify four main regions based on velocities that have H2 column densities ranging from 2×1020 cm-2 - 1.3×1022 cm-2. The average X(CO) is close to the galactic average, with variations below X Gal from collisional de-excitation in low-density gas, and above X Gal from CO photodissociation at cloud edges. The hierarchical structures follow a broken power law mass-size relation M=ARα. The values of α vir ranged from 3-60, with the smallest values at 0.1 pc scales. The mass-size relations for the structures with the lowest α vir have scaling factors A three times larger than those of high α vir structures, indicating external pressure one order of magnitude larger. We found a transition of parallel to perpendicular between column density structures and magnetic field orientations at N(H2) = 4.5 × 1021 cm-2. We provide the first integrated chemical, dynamical, and magnetic field analysis of MBM12. Scale-dependent mass-size and virial analysis can further constrain the role of external pressure in regulating the star formation efficiency.