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Quantifying the informativity of emission lines to infer physical conditions in giant molecular clouds. I. Application to model predictions
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Quantifying the informativity of emission lines to infer physical conditions in giant molecular clouds. I. Application to model predictions
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Quantifying the informativity of emission lines to infer physical conditions in giant molecular clouds. I. Application to model predictions
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Paper
Quantifying the informativity of emission lines to infer physical conditions in giant molecular clouds. I. Application to model predictions
2024
Overview
Observations of ionic, atomic, or molecular lines are performed to improve our understanding of the interstellar medium (ISM). However, the potential of a line to constrain the physical conditions of the ISM is difficult to assess quantitatively, because of the complexity of the ISM physics. The situation is even more complex when trying to assess which combinations of lines are the most useful. Therefore, observation campaigns usually try to observe as many lines as possible for as much time as possible. We search for a quantitative statistical criterion to evaluate the constraining power of a (or combination of) tracer(s) with respect to physical conditions in order to improve our understanding of the statistical relationships between ISM tracers and physical conditions and helps observers to motivate their observation proposals. The best tracers are obtained by comparing the mutual information between a physical parameter and different sets of lines. We apply this method to simulations of radio molecular lines emitted by a photodissociation region similar to the Horsehead Nebula that would be observed at the IRAM 30m telescope. We search for the best lines to constrain the visual extinction \\(A_v^{tot}\\) or the far UV illumination \\(G_0\\). The most informative lines change with the physical regime (e.g., cloud extinction). Short integration time of the CO isotopologue \\(J=1-0\\) lines already yields much information on the total column density most regimes. The best set of lines to constrain the visual extinction does not necessarily combine the most informative individual lines. Precise constraints on \\(G_0\\) are more difficult to achieve with molecular lines. They require spectral lines emitted at the cloud surface (e.g., [CII] and [CI] lines). This approach allows one to better explore the knowledge provided by ISM codes, and to guide future observation campaigns.
Publisher
Cornell University Library, arXiv.org
