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| Main Authors: | , , , , , , |
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| Format: | Preprint |
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2025
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2503.20944 |
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| _version_ | 1866912411631484928 |
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| author | Giannetti, A. Leurini, S. Schisano, E. Casasola, V. Pillai, T. G. S. Sanna, C. Ferrada-Chamorro, S. |
| author_facet | Giannetti, A. Leurini, S. Schisano, E. Casasola, V. Pillai, T. G. S. Sanna, C. Ferrada-Chamorro, S. |
| contents | Almost all the physics of star formation critically depends on the number density of the molecular gas. However, the methods to estimate this key property often rely on uncertain assumptions about geometry, depend on overly simplistic uniform models, or require time-expensive observations to constrain the gas temperature as well. An easy-to-use method to derive n(H2) that is valid under realistic conditions is absent, causing an asymmetry in how accurately this parameter is estimated, and how often dedicated tracers are used, compared to the gas temperature. We propose and calibrate a versatile tool based on CH3OH lines that greatly simplifies the inference of the number density. CH3OH is abundant in both cold and hot gas, and thus it can be applied to a wide variety of scales. Moreover, this tool does not need to be tailored to the specific source properties (e.g. distance, temperature, and mass). We perform RT calculations to investigate the robustness of the line ratios as density probes, also in the presence of density and temperature gradients. We find that the ratios of the (2_K-1_K) band transitions constrain the average n(H2) along the LOS within a factor of 2-3 in the range 5 x 10^4 - 3 x 10^7 cm^-3. The range can be extended down to a few times 10^3 cm^-3, when also using line ratios from the (5_K-4_K) and/or (7_K-6_K) bands. We provide practical analytic formulas and a numerical method for deriving n(H2) and its uncertainty from the line ratios. Thanks to our calibration and analytical recipes, we make the estimate of n(H2) much simpler, with an effort comparable or inferior to deriving Tex, contributing to offsetting the disparity between these two fundamental parameters of the molecular gas. Applying our method to a sub-sample of sources from the ATLASGAL TOP100 we show that the material in the clumps is being compressed, accelerating in the latest stages. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2503_20944 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | CH$_3$OH as a User-Friendly Density Probe: Calibration and Beyond Giannetti, A. Leurini, S. Schisano, E. Casasola, V. Pillai, T. G. S. Sanna, C. Ferrada-Chamorro, S. Astrophysics of Galaxies Almost all the physics of star formation critically depends on the number density of the molecular gas. However, the methods to estimate this key property often rely on uncertain assumptions about geometry, depend on overly simplistic uniform models, or require time-expensive observations to constrain the gas temperature as well. An easy-to-use method to derive n(H2) that is valid under realistic conditions is absent, causing an asymmetry in how accurately this parameter is estimated, and how often dedicated tracers are used, compared to the gas temperature. We propose and calibrate a versatile tool based on CH3OH lines that greatly simplifies the inference of the number density. CH3OH is abundant in both cold and hot gas, and thus it can be applied to a wide variety of scales. Moreover, this tool does not need to be tailored to the specific source properties (e.g. distance, temperature, and mass). We perform RT calculations to investigate the robustness of the line ratios as density probes, also in the presence of density and temperature gradients. We find that the ratios of the (2_K-1_K) band transitions constrain the average n(H2) along the LOS within a factor of 2-3 in the range 5 x 10^4 - 3 x 10^7 cm^-3. The range can be extended down to a few times 10^3 cm^-3, when also using line ratios from the (5_K-4_K) and/or (7_K-6_K) bands. We provide practical analytic formulas and a numerical method for deriving n(H2) and its uncertainty from the line ratios. Thanks to our calibration and analytical recipes, we make the estimate of n(H2) much simpler, with an effort comparable or inferior to deriving Tex, contributing to offsetting the disparity between these two fundamental parameters of the molecular gas. Applying our method to a sub-sample of sources from the ATLASGAL TOP100 we show that the material in the clumps is being compressed, accelerating in the latest stages. |
| title | CH$_3$OH as a User-Friendly Density Probe: Calibration and Beyond |
| topic | Astrophysics of Galaxies |
| url | https://arxiv.org/abs/2503.20944 |