Photoevaporation of Jeans-unstable molecular clumps

Decataldo, D.; Pallottini, Andrea; Ferrara, Andrea; Vallini, L.; Gallerani, S.

doi:10.1093/mnras/stz1527

Cited by 38 publications

(37 citation statements)

References 93 publications

(115 reference statements)

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“…That the HCN clumps detected in Mrk 231's outflow correspond to star forming complexes is a very interesting prospect, especially in the context of the new scenarios predicting the formation of stars inside outflows. Indeed, dense and clumpy gas are conditions that typically result into rapid gravitational collapse and star formation (Decataldo et al 2019); hence our finding provides further support for this new mode of star formation.…”

Section: Dense Clumps Embedded In the Outflowsupporting

confidence: 70%

“…The prominent CN line wings of Mrk 231 may indicate that the outflow is bathed in a strong UV radiation field, either due to star formation in the galaxy disk or to new stars forming within the outflow itself. The latter is a scenario proposed by various recent models and simulations (Zubovas et al 2013;Zubovas & King 2014;Ishibashi & Fabian 2012;Ishibashi et al 2013;El-Badry et al 2016;Wang & Loeb 2018;Decataldo et al 2019). Star formation in the outflow could have major implications, since such stars would have highly radial orbit and could, for instance, contribute to the formation of…”

Section: Enhanced Cn/hcn Abundance Ratiosmentioning

confidence: 93%

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Enhanced UV radiation and dense clumps in the molecular outflow of Mrk 231

Cicone

Maiolino

Aalto

et al. 2020

A&A

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We present interferometric observations of the CN(1-0) line emission in Mrk 231 and combine them with previous observations of CO and other H 2 gas tracers to study the physical properties of the massive molecular outflow. We find a strong boost of the CN/CO(1-0) line luminosity ratio in the outflow, which is unprecedented compared to any other known Galactic or extragalactic source. For the dense gas phase in the outflow traced by the HCN and CN emissions, we infer X CN ≡ [CN]/[H 2 ] > X HCN by at least a factor of three, with H 2 gas densities of n H 2 ∼ 10 5−6 cm −3 . In addition, for the first time, we resolve narrow spectral features in the HCN(1-0) and HCO + (1-0) high-velocity line wings tracing the dense phase of the outflow. The velocity dispersions of these spectral features, σ v ∼ 7 − 20 km s −1 , are consistent with those of massive extragalactic giant molecular clouds detected in nearby starburst nuclei. The H 2 gas masses inferred from the HCN data are quite high, M mol ∼ 0.3 − 5 × 10 8 M . Our results suggest that massive, denser molecular gas complexes survive embedded into the more diffuse H 2 phase of the outflow, and that the chemistry of such outflowing dense clouds is affected by enhanced UV radiation.

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Section: Dense Clumps Embedded In the Outflowsupporting

confidence: 70%

Section: Enhanced Cn/hcn Abundance Ratiosmentioning

confidence: 93%

Enhanced UV radiation and dense clumps in the molecular outflow of Mrk 231

Cicone

Maiolino

Aalto

et al. 2020

A&A

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“…Rosdahl et al 2013). This has the effect that in the case where radiation from many sources is mixed, the radiation flux becomes distorted, by up to a factor two (Decataldo et al 2019), compared to the real flux which can for example be obtained with ray-tracing methods. These more accurate methods, however, are prohibitively expensive to use in simulations with the number of resolution elements and, more importantly, number of radiation sources that we model in this work.…”

Section: Simulationsmentioning

confidence: 99%

EDGE: the mass–metallicity relation as a critical test of galaxy formation physics

Agertz

Pontzen

Read

et al. 2019

Monthly Notices of the Royal Astronomical Society

137

177

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We introduce the "Engineering Dwarfs at Galaxy formation's Edge" (EDGE) project to study the cosmological formation and evolution of the smallest galaxies in the Universe. In this first paper, we explore the effects of resolution and sub-grid physics on a single low mass halo (M halo = 10 9 M ), simulated to redshift z = 0 at a mass and spatial resolution of ∼ 20 M and ∼ 3 pc. We consider different star formation prescriptions, supernova feedback strengths and on-the-fly radiative transfer (RT). We show that RT changes the mode of galactic self-regulation at this halo mass, suppressing star formation by causing the interstellar and circumgalactic gas to remain predominantly warm (∼ 10 4 K) even before cosmic reionisation. By contrast, without RT, star formation regulation occurs only through starbursts and their associated vigorous galactic outflows. In spite of this difference, the entire simulation suite (with the exception of models without any feedback) matches observed dwarf galaxy sizes, velocity dispersions, V-band magnitudes and dynamical mass-to-light-ratios. This is because such structural scaling relations are predominantly set by the host dark matter halo, with the remaining model-to-model variation being smaller than the observational scatter. We find that only the stellar mass-metallicity relation differentiates the galaxy formation models. Explosive feedback ejects more metals from the dwarf, leading to a lower metallicity at a fixed stellar mass. We conclude that the stellar mass-metallicity relation of the very smallest galaxies provides a unique constraint on galaxy formation physics.

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“…In this situation, radiative feedback (e.g. due to radiation from massive stars) can be more effective, causing for instance the photoevaporation of molecular clouds (Gorti & Hollenbach 2002;Decataldo et al 2017Decataldo et al , 2019. This process indirectly regulates the line luminosity resulting from the associated photo-dissociation regions (Vallini et al 2017).…”

Section: Introductionmentioning

confidence: 99%

A physical model for [C ii] line emission from galaxies

Ferrara

Vallini

Pallottini

et al. 2019

Monthly Notices of the Royal Astronomical Society

Self Cite

111

138

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A tight relation between the [C ii] 158 $\mu$m line luminosity and star formation rate is measured in local galaxies. At high redshift (z > 5), though, a much larger scatter is observed, with a considerable (15–20 per cent) fraction of the outliers being [C ii]-deficient. Moreover, the [C ii] surface brightness ($\Sigma_{\rm [C\, \small {II}]}$) of these sources is systematically lower than expected from the local relation. To clarify the origin of such [C ii]-deficiency, we have developed an analytical model that fits local [C ii] data and has been validated against radiative transfer simulations performed with cloudy. The model predicts an overall increase of $\Sigma_{\rm [C\, \small {II}]}$ with ΣSFR. However, for ΣSFR ${\gtrsim} 1 \, \mathrm{M}_\odot \,{\rm yr}^{-1}\,{\rm kpc}^{-2}$, $\Sigma_{\rm [C\, \small {II}]}$ saturates. We conclude that underluminous [C ii] systems can result from a combination of three factors: (a) large upward deviations from the Kennicutt–Schmidt relation (κs ≫ 1), parametrized by the ‘burstiness’ parameter κs; (b) low metallicity; (c) low gas density, at least for the most extreme sources (e.g. CR7). Observations of [C ii] emission alone cannot break the degeneracy among the above three parameters; this requires additional information coming from other emission lines (e.g. [O iii]88 $\mu$m, C iii]1909 Å, CO lines). Simple formulae are given to interpret available data for low- and high-z galaxies.

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Photoevaporation of Jeans-unstable molecular clumps

Cited by 38 publications

References 93 publications

Enhanced UV radiation and dense clumps in the molecular outflow of Mrk 231

Enhanced UV radiation and dense clumps in the molecular outflow of Mrk 231

EDGE: the mass–metallicity relation as a critical test of galaxy formation physics

A physical model for [C ii] line emission from galaxies

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