The origin and evolution of the [CII] deficit in HII regions and star-forming molecular clouds
Abstract
We analyse synthetic maps of the [CII] 158 μm line and FIR continuum of simulated molecular clouds (MCs) within the SILCC-Zoom project to study the origin of the [CII] deficit, i.e., the drop in the [CII]/FIR intensity ratio. All simulations include stellar radiative feedback and account for further ionisation of C+ into C2+ inside HII regions. For individual HII regions, IFIR is initially high in the vicinity of young stars, and then moderately decreases as the gas is compressed into shells. In contrast, ICII drops strongly over time, to which the second ionisation of C+ into C2+ contributes. This leads to a large drop in I[CII]/IFIR inside HII regions, decreasing from 10-3-10-2 at scales above 10 pc to 10-6-10-4 at scales below 2pc. However, projection effects can affect the radial profile of I[CII] and IFIR and create apparent HII regions without any stars. On MC scales, L[CII]/LFIR decreases from values 10-2 in MCs without star formation to values around 10-3 in MCs with star formation. We attribute this and the origin of the [CII] deficit to two main contributors: (i) the saturation of the [CII] line and (ii) the conversion of C+ into C2+ by stellar radiation. The drop in L[CII]/LFIR can be divided into two phases: (i) early on, the saturation of [CII] and the further ionisation of C+ limit the increase in L[CII], while LFIR increases rapidly, leading to the initial decline of L[CII]/LFIR. (ii) In more evolved HII regions, LCII stagnates and even partially drops due to the aforementioned reasons. LFIR stagnates as the gas gets pushed into the cooler shells keeping L[CII]/LFIR at low values of 10-3.
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