CLusters in the Uv as EngineS (CLUES). II. Subkiloparsec-scale Outflows Driven by Stellar Feedback

Sirressi, Mattia; Adamo, Angela; Hayes, Matthew; Rivera-Thorsen, Thøger Emil; Aloisi, Alessandra; Bik, Arjan; Calzetti, Daniela; Chisholm, John; Fox, Andrew J.; Fumagalli, Michele; Grasha, Kathryn; Hernandez, Svea; Messa, Matteo; Osborne, Shannon; Östlin, Göran; Sabbi, Elena; Schinnerer, Eva; Smith, Linda J.; Usher, Christopher; Wofford, Aida

doi:10.3847/1538-3881/ad29f9

Cited by 1 publication

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“…Our Starburst99 simulation suggests that the YMCs can together produce a mechanical luminosity of ∼2 × 10 40 erg s −1 , or a total deposited mechanical energy of ∼3 × 10 54 erg over 4 Myr. A mere 2% energy retention factor (easily reachable for stellar wind and supernova-driven outflows; see Kim et al 2020;Sirressi et al 2024) would be enough to power the ionized gas outflow reported by Leaman et al (2019) and to heat the X-ray emitting gas studied by Swartz et al (2006). These order-of-magnitude calculations suggest that the current population of YMCs will be more than capable of driving gas outflow at a similar level in the future.…”

Section: Ymcs In Large-scale Contextmentioning

confidence: 99%

Hidden Gems on a Ring: Infant Massive Clusters and Their Formation Timeline Unveiled by ALMA, HST, and JWST in NGC 3351

Sun 孙,

He 何,

Batschkun

et al. 2024

ApJ

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We use 0.1″ observations from the Atacama Large Millimeter Array (ALMA), Hubble Space Telescope (HST), and JWST to study young massive clusters (YMCs) in their embedded “infant” phase across the central starburst ring in NGC 3351. Our new ALMA data reveal 18 bright and compact (sub-)millimeter continuum sources, of which 8 have counterparts in JWST images and only 6 have counterparts in HST images. Based on the ALMA continuum and molecular line data, as well as ancillary measurements for the HST and JWST counterparts, we identify 14 sources as infant star clusters with high stellar and/or gas masses (∼105 M ⊙), small radii (≲ 5 pc), large escape velocities (6–10 km s−1), and short freefall times (0.5–1 Myr). Their multiwavelength properties motivate us to divide them into four categories, likely corresponding to four evolutionary stages from starless clumps to exposed H ii region–cluster complexes. Leveraging age estimates for HST-identified clusters in the same region, we infer an evolutionary timeline, ranging from ∼1–2 Myr before cluster formation as starless clumps, to ∼4–6 Myr after as exposed H ii region–cluster complexes. Finally, we show that the YMCs make up a substantial fraction of recent star formation across the ring, exhibit a nonuniform azimuthal distribution without a very coherent evolutionary trend along the ring, and are capable of driving large-scale gas outflows.

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