Application of Resolved Low-J Multi-CO Line Modeling with RADEX to Constrain the Molecular Gas Properties in the Starburst M82

Application of Resolved Low-J Multi-CO Line Modeling with RADEX to Constrain the Molecular Gas Properties in the Starburst M82

The distribution and physical conditions of molecular gas are closely linked to star formation and the subsequent evolution of galaxies. Emission from carbon monoxide (CO) and its isotopologues traces the bulk of molecular gas and provides constraints on the physical conditions through their line ra...

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Main Authors: Valencia Zhang, Jakob den Brok, Qizhou Zhang, Yu-Hsuan Teng, María J. Jiménez-Donaire, Eric W. Koch, Antonio Usero, Fabian Walter, Leindert Boogaard, Craig Yanitski, Cosima Eibensteiner, Ivana Bešlic, Juan Luis Verbena
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astrophysical Journal
Subjects:
Starburst galaxies
Interstellar medium
Molecular gas
Molecular spectroscopy
Millimeter-wave spectroscopy
Star formation
Online Access:https://doi.org/10.3847/1538-4357/adb579
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Summary:The distribution and physical conditions of molecular gas are closely linked to star formation and the subsequent evolution of galaxies. Emission from carbon monoxide (CO) and its isotopologues traces the bulk of molecular gas and provides constraints on the physical conditions through their line ratios. However, a comprehensive understanding of how the particular choice of line modeling approach impacts derived molecular properties remains incomplete. Here, we study the nearby starburst galaxy M82, known for its intense star formation and molecular emission, using the large set of available multi-CO line observations. We present high-resolution (∼85 pc) emission of seven CO isotopologue lines, including ^12 CO, ^13 CO, and C ^18 O from the J  = 1–0, 2–1, and 3–2 transitions. Using RADEX for radiative transfer modeling, we analyze M82’s molecular properties with (i) a one-zone model and (ii) a variable density model, comparing observed and simulated emissions via a minimum χ ^2 analysis. We find that inferred gas conditions—kinetic temperature and density—are consistent across models, with minimal statistical differences. However, due to their low critical densities (<10 ^4 cm ^−3 ), low- J CO isotopologue lines do not effectively probe higher-density gas prevalent in starburst environments like that of M82. Our results further imply that this limitation extends to high-redshift ( z  ⪆ 1) galaxies with similar conditions, where low- J CO lines are inadequate for density constraints. Future studies of extreme star-forming regions like M82 will require higher- J CO lines or alternative molecular tracers with higher critical densities.
ISSN:1538-4357

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