The Molecular Cloud Life Cycle. II. Formation and Destruction of Molecular Clouds Diagnosed via H2 Fluorescent Emission

Molecular hydrogen (H2) formation and dissociation are key processes that drive the gas life cycle in galaxies. Using the SImulating the LifeCycle of Molecular Clouds zoom-in simulation suite, we explore the utility of future observations of H2 dissociation and formation for tracking the life cycle...

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Published inThe Astrophysical journal Vol. 975; no. 2; p. 269
Main Authors Burkhart, Blakesley, Bialy, Shmuel, Seifried, Daniel, Walch, Stefanie, Hamden, Erika, Haworth, Thomas J, Hoadley, Keri, Kong, Shuo, Johnson, Madisen, Jeffreson, Sarah, Krumholz, Mark R, Min-Young, Lee, Sternberg, Amiel, Turner, Neal J
Format Journal Article
LanguageEnglish
Published Philadelphia IOP Publishing 01.11.2024
Subjects
Astrochemistry
Atomic properties
Cloud formation
Dissociation
Early stars
Fluorescence
Galaxies
Life cycles
Molecular clouds
Star & galaxy formation
Star formation
Star formation rate
Stars
Stellar evolution
Stellar radiation
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Summary:Molecular hydrogen (H2) formation and dissociation are key processes that drive the gas life cycle in galaxies. Using the SImulating the LifeCycle of Molecular Clouds zoom-in simulation suite, we explore the utility of future observations of H2 dissociation and formation for tracking the life cycle of molecular clouds. The simulations used in this work include nonequilibrium H2 formation, stellar radiation, sink particles, and turbulence. We find that at early times in the cloud evolution H2 formation rapidly outpaces dissociation and molecular clouds build their mass from the atomic reservoir in their environment. Rapid H2 formation is also associated with a higher early star formation rate. For the clouds studied here, H2 is strongly out of chemical equilibrium during the early stages of cloud formation but settles into a bursty chemical steady state about 2 Myr after the first stars form. At the latest stage of cloud evolution, dissociation outweighs formation and the clouds enter a dispersal phase. We discuss how theories of the molecular cloud life cycle and star formation efficiency may be distinguished with observational measurements of H2 fluorescence with a space-based high-resolution far-UV spectrometer, such as the proposed Hyperion and Eos NASA Explorer missions. Such missions would enable measurements of the H2 dissociation and formation rates, which we demonstrate can be connected to different phases in a molecular cloud’s star-forming life, including cloud building, rapidly star forming, H2 chemical equilibrium, and cloud destruction.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ad75f8