Synthetic [CII] emission maps of a simulated molecular cloud in formation

Abstract

The C+ ion is an important coolant of interstellar gas, and so the [CII] fine structure line is frequently observed in the interstellar medium. However, the physical and chemical properties of the [CII]-emitting gas are still unclear. We carry out non-LTE radiative transfer simulations with RADMC-3D to study the [CII] line emission from a young, turbulent molecular cloud before the onset of star formation, using data from the SILCC-Zoom project. The [CII] emission is optically thick over 40% of the observable area with I[CII] > 0.5 K km s-1. To determine the physical properties of the [CII] emitting gas, we treat the [CII] emission as optically thin. We find that the [CII] emission originates primarily from cold, moderate density gas (40 T 65 K and 50 n 440 cm-3), composed mainly of atomic hydrogen and with an effective visual extinction between 0.50 and 0.91. Gas dominated by molecular hydrogen contributes only 20% of the total [CII] line emission. Thus, [CII] is not a good tracer for CO-dark H2 at this early phase in the cloud's lifetime. We also find that the total gas, H and C+ column densities are all correlated with the integrated [CII] line emission, with power law slopes ranging from 0.5 to 0.7. Further, the median ratio between the total column density and the [CII] line emission is Y CII≈ 1.1 × 1021 cm-2 (K km s-1)-1, and Y CII scales with I[CII]-0.3. We expect Y CII to change in environments with a lower or higher radiation field than simulated here.