The SILCC project – III. Regulation of star formation and outflows by stellar winds and supernovae

Gatto, Andrea; Walch, Stefanie; Naab, Thorsten; Girichidis, Philipp; Wünsch, Richard; Glover, Simon C. O.; Klessen, Ralf S.; Clark, Paul; Peters, Thomas; Derigs, Dominik; Baczynski, Christian; Puls, J.

doi:10.1093/mnras/stw3209

Cited by 197 publications

(205 citation statements)

References 127 publications

(116 reference statements)

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“…18), as it is the over-pressurized hot gas that drives the outflows. Our result is in very good agreement with recent studies such as Walch et al (2015), Girichidis et al (2016b) or Gatto et al (2017). In addition to the effect of photoionization, we find that the adopted stellar lifetime also has an important effect on nSNII.…”

Section: Discussionsupporting

confidence: 93%

“…Including photoionization helps suppress star formation, as PE-PI-SN-cmp and noPE-PI-SNcmp both show much lower SFRs. This highlights the importance of feedback from massive stars prior to their SN events on regulating star formation in the higher gas surface density regime (see also Gatto et al (2017) who investigated the importance of stellar winds in a Milky Way setup). The fact that PE-PI-SN-cmp and noPE-PI-SN-cmp both have very similar SFR is consistent with our previous study in Paper I where we found that the SFR in dwarf galaxies is insensitive to the adopted value of G0 (constant field).…”

Section: Global Propertiesmentioning

confidence: 73%

“…On scales below a few parsecs, the most commonly adopted sub-resolution model is the 'sink particle' approach (Bate, Bonnell & Price 1995;Li, Mac Low & Klessen 2005;Federrath et al 2010;Hubber, Walch & Whitworth 2013;Gatto et al 2017). The idea is that when a region of gas is so gravitationally unstable that it will inevitably collapse and form stars, one can simply convert it into a 'sink particle' which only interacts gravitationally but not hydrodynamically with the rest of the system.…”

Section: Star Formationmentioning

confidence: 99%

“…Another important feedback mechanism we have ignored is the stellar winds from massive stars, which can play a similar role as photoionization in the sense that they both can create favorable low-density environments for the subsequent SNe to be efficient and thus promote outflows (Gatto et al 2017;Peters et al 2016). We have neglected them in this study for two reasons, one numerical and one physical.…”

Section: Stellar Windsmentioning

confidence: 99%

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Variable interstellar radiation fields in simulated dwarf galaxies: supernovae versus photoelectric heating

Naab

Glover

et al. 2017

Monthly Notices of the Royal Astronomical Society

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We present high-resolution hydrodynamical simulations of isolated dwarf galaxies including self-gravity, non-equilibrium cooling and chemistry, interstellar radiation fields (IRSF) and shielding, star formation, and stellar feedback. This includes spatially and temporally varying photoelectric (PE) heating, photoionization, resolved supernova (SN) blast waves and metal enrichment. A new flexible method to sample the stellar initial mass function allows us to follow the contribution to the ISRF, the metal output and the SN delay times of individual massive stars. We find that SNe play the dominant role in regulating the global star formation rate, shaping the multi-phase interstellar medium (ISM) and driving galactic outflows. Outflow rates (with massloading factors of a few) and hot gas fractions of the ISM increase with the number of SNe exploding in low-density environments where radiative energy losses are low. While PE heating alone can suppress star formation slightly more (a factor of a few) than SNe alone can do, it is unable to drive outflows and reproduce the multi-phase ISM that emerges naturally when SNe are included. These results are in conflict with recent results of Forbes et al. who concluded that PE heating is the dominant process suppressing star formation in dwarfs, about an order of magnitude more efficient than SNe. Potential origins for this discrepancy are discussed. In the absence of SNe and photoionization (mechanisms to disperse dense clouds), the impact of PE heating is highly overestimated owing to the (unrealistic) proximity of dense gas to the radiation sources. This leads to a substantial boost of the infrared continuum emission from the UV-irradiated dust and a far infrared line-to-continuum ratio too low compared to observations. Though sub-dominant in regulating star formation, the ISRF controls the abundance of molecular hydrogen via photodissociation.

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Section: Discussionsupporting

confidence: 93%

Section: Global Propertiesmentioning

confidence: 73%

Section: Star Formationmentioning

confidence: 99%

Section: Stellar Windsmentioning

confidence: 99%

See 2 more Smart Citations

Variable interstellar radiation fields in simulated dwarf galaxies: supernovae versus photoelectric heating

Naab

Glover

et al. 2017

Monthly Notices of the Royal Astronomical Society

Self Cite

124

222

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“…These results illustrate the importance of considering FUV feedback in understanding the star formation activity of galactic disk systems. Similar conclusions have been reached by Peters et al (2017) in their lower (4 pc) resolution studies of a smaller (0.5 kpc by 0.5 kpc) disk patch, which builds on the previous study of a stellar wind and supernova feedback model by Gatto et al (2017).…”

Section: Discussionsupporting

confidence: 85%

Kiloparsec-scale Simulations of Star Formation in Disk Galaxies. IV. Regulation of Galactic Star Formation Rates by Stellar Feedback

Butler

Tan

Teyssier

et al. 2017

ApJ

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Star formation from the interstellar medium of galactic disks is a basic process controlling the evolution of galaxies. Understanding the star formation rate (SFR) in a local patch of a disk with a given gas mass is thus an important challenge for theoretical models. Here we simulate a kiloparsec region of a disk, following the evolution of self-gravitating molecular clouds down to subparsec scales, as they form stars that then inject feedback energy by dissociating and ionizing UV photons and supernova explosions. We assess the relative importance of each feedback mechanism. We find that H 2 -dissociating feedback results in the largest absolute reduction in star formation compared to the run with no feedback. Subsequently adding photoionization feedback produces a more modest reduction. Our fiducial models that combine all three feedback mechanisms yield, without fine-tuning, SFRs that are in excellent agreement with observations, with H 2 -dissociating photons playing a crucial role. Models that only include supernova feedback-a common method in galaxy evolution simulations-settle to similar SFRs, but with very different temperatures and chemical states of the gas, and with very different spatial distributions of young stars.

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The Molecular Cloud Lifecycle

et al. 2020

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Giant molecular clouds (GMCs) and their stellar offspring are the building blocks of galaxies. The physical characteristics of GMCs and their evolution are tightly connected to galaxy evolution. The macroscopic properties of the interstellar medium propagate into the properties of GMCs condensing out of it, with correlations between e.g. the galactic and GMC scale gas pressures, surface densities and volume densities. That way, the galactic environment sets the initial conditions for star formation within GMCs. After the onset of massive star formation, stellar feedback from e.g. photoionisation, stellar winds, and supernovae eventually contributes to dispersing the parent cloud, depositing energy, momentum and metals into the surrounding medium, thereby changing the properties of galaxies. This cycling of matter between gas and stars, governed by star formation and feedback, is therefore a major driver of galaxy evolution. Much of the recent debate has focused on the durations of the various evolutionary phases that constitute this cycle in galaxies, and what these can teach us about the physical mechanisms driving the cycle. We review results from observational, theoretical, and numerical work to build a dynamical picture of the evolutionary lifecycle of GMC evolution, star formation, and feedback in galaxies.

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The SILCC project – III. Regulation of star formation and outflows by stellar winds and supernovae

Cited by 197 publications

References 127 publications

Variable interstellar radiation fields in simulated dwarf galaxies: supernovae versus photoelectric heating

Variable interstellar radiation fields in simulated dwarf galaxies: supernovae versus photoelectric heating

Kiloparsec-scale Simulations of Star Formation in Disk Galaxies. IV. Regulation of Galactic Star Formation Rates by Stellar Feedback

The Molecular Cloud Lifecycle

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