When feedback fails: The scaling and saturation of star formation efficiency

Michael Y. Grudić; Philip F. Hopkins; Claude André Faucher-Giguère; Eliot Quataert; Norman Murray; Dušan Kereš

doi:10.1093/MNRAS/STY035

When feedback fails: The scaling and saturation of star formation efficiency

Michael Y. Grudić^*, Philip F. Hopkins, Claude André Faucher-Giguère, Eliot Quataert, Norman Murray, Dušan Kereš

^*Corresponding author for this work

Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

145 Scopus citations

Abstract

We present a suite of 3D multiphysics MHD simulations following star formation in isolated turbulent molecular gas discs ranging from 5 to 500 parsecs in radius. These simulations are designed to survey the range of surface densities between those typical of Milky Way giant molecular clouds (GMCs) (~ 10²M_⊙ pc^-2) and extreme ultraluminous infrared galaxy environments (~ 10⁴M_⊙ pc^-2) so as to map out the scaling of the cloud-scale star formation efficiency (SFE) between these two regimes. The simulations include prescriptions for supernova, stellar wind, and radiative feedback, which we find to be essential in determining both the instantaneous per-freefall (∈_ff) and integrated (∈_int) star formation efficiencies. In all simulations, the gas discs form stars until a critical stellar surface density has been reached and the remaining gas is blown out by stellar feedback. We find that surface density is a good predictor of ∈_int, as suggested by analytic force balance arguments from previous works. SFE eventually saturates to ~ 1 at high surface density. We also find a proportional relationship between ∈_ff and ∈_int, implying that star formation is feedback-moderated even over very short time-scales in isolated clouds. These results have implications for star formation in galactic discs, the nature and fate of nuclear starbursts, and the formation of bound star clusters. The scaling of ∈_ff with surface density is not consistent with the notion that ∈_ff is always ~ 1 per cent on the scale of GMCs, but our predictions recover the ~ 1 per cent value for GMC parameters similar to those found in spiral galaxies, including our own.

Original language	English (US)
Pages (from-to)	3511-3528
Number of pages	18
Journal	Monthly Notices of the Royal Astronomical Society
Volume	475
Issue number	3
DOIs	https://doi.org/10.1093/MNRAS/STY035
State	Published - Apr 2018

Funding

We thank Neal J. Evans II, Eve Ostriker, Dávid Guszejnov, Chris Hayward, Matthew Orr and Andrew Wetzel for helpful comments and critique. We also thank the anonymous referees for highly comprehensive and helpful feedback that motivated a more thorough understanding of our results. Support for PFH and MYG was provided by an Alfred P. Sloan Research Fellowship, NASA ATP Grant NNX14AH35G and NSF Collaborative Research Grant #1411920 and CAREER grant #1455342. Numerical calculations were run on the Caltech computer cluster 'Zwicky' (NSF MRI award #PHY-0960291) and allocation TG-AST130039 granted by the Extreme Science and Engineering Discovery Environment (XSEDE) supported by the NSF.

Keywords

Galaxies: active
Galaxies: nuclei
Galaxies: star clusters: general
Galaxies: star formation
Galaxies: starburst

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

Access to Document

10.1093/MNRAS/STY035

Cite this

@article{490fa0dad93344b78f79a9a1b877bf14,

title = "When feedback fails: The scaling and saturation of star formation efficiency",

abstract = "We present a suite of 3D multiphysics MHD simulations following star formation in isolated turbulent molecular gas discs ranging from 5 to 500 parsecs in radius. These simulations are designed to survey the range of surface densities between those typical of Milky Way giant molecular clouds (GMCs) (~ 102M⊙ pc-2) and extreme ultraluminous infrared galaxy environments (~ 104M⊙ pc-2) so as to map out the scaling of the cloud-scale star formation efficiency (SFE) between these two regimes. The simulations include prescriptions for supernova, stellar wind, and radiative feedback, which we find to be essential in determining both the instantaneous per-freefall (∈ff) and integrated (∈int) star formation efficiencies. In all simulations, the gas discs form stars until a critical stellar surface density has been reached and the remaining gas is blown out by stellar feedback. We find that surface density is a good predictor of ∈int, as suggested by analytic force balance arguments from previous works. SFE eventually saturates to ~ 1 at high surface density. We also find a proportional relationship between ∈ff and ∈int, implying that star formation is feedback-moderated even over very short time-scales in isolated clouds. These results have implications for star formation in galactic discs, the nature and fate of nuclear starbursts, and the formation of bound star clusters. The scaling of ∈ff with surface density is not consistent with the notion that ∈ff is always ~ 1 per cent on the scale of GMCs, but our predictions recover the ~ 1 per cent value for GMC parameters similar to those found in spiral galaxies, including our own.",

keywords = "Galaxies: active, Galaxies: nuclei, Galaxies: star clusters: general, Galaxies: star formation, Galaxies: starburst",

author = "Grudi{\'c}, {Michael Y.} and Hopkins, {Philip F.} and Faucher-Gigu{\`e}re, {Claude Andr{\'e}} and Eliot Quataert and Norman Murray and Du{\v s}an Kere{\v s}",

note = "Funding Information: We thank Neal J. Evans II, Eve Ostriker, D{\'a}vid Guszejnov, Chris Hayward, Matthew Orr and Andrew Wetzel for helpful comments and critique. We also thank the anonymous referees for highly comprehensive and helpful feedback that motivated a more thorough understanding of our results. Support for PFH and MYG was provided by an Alfred P. Sloan Research Fellowship, NASA ATP Grant NNX14AH35G and NSF Collaborative Research Grant #1411920 and CAREER grant #1455342. Numerical calculations were run on the Caltech computer cluster 'Zwicky' (NSF MRI award #PHY-0960291) and allocation TG-AST130039 granted by the Extreme Science and Engineering Discovery Environment (XSEDE) supported by the NSF. Publisher Copyright: {\textcopyright} 2018 The Author(s).",

year = "2018",

month = apr,

doi = "10.1093/MNRAS/STY035",

language = "English (US)",

volume = "475",

pages = "3511--3528",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "Oxford University Press",

number = "3",

}

TY - JOUR

T1 - When feedback fails

T2 - The scaling and saturation of star formation efficiency

AU - Grudić, Michael Y.

AU - Hopkins, Philip F.

AU - Faucher-Giguère, Claude André

AU - Quataert, Eliot

AU - Murray, Norman

AU - Kereš, Dušan

N1 - Funding Information: We thank Neal J. Evans II, Eve Ostriker, Dávid Guszejnov, Chris Hayward, Matthew Orr and Andrew Wetzel for helpful comments and critique. We also thank the anonymous referees for highly comprehensive and helpful feedback that motivated a more thorough understanding of our results. Support for PFH and MYG was provided by an Alfred P. Sloan Research Fellowship, NASA ATP Grant NNX14AH35G and NSF Collaborative Research Grant #1411920 and CAREER grant #1455342. Numerical calculations were run on the Caltech computer cluster 'Zwicky' (NSF MRI award #PHY-0960291) and allocation TG-AST130039 granted by the Extreme Science and Engineering Discovery Environment (XSEDE) supported by the NSF. Publisher Copyright: © 2018 The Author(s).

PY - 2018/4

Y1 - 2018/4

N2 - We present a suite of 3D multiphysics MHD simulations following star formation in isolated turbulent molecular gas discs ranging from 5 to 500 parsecs in radius. These simulations are designed to survey the range of surface densities between those typical of Milky Way giant molecular clouds (GMCs) (~ 102M⊙ pc-2) and extreme ultraluminous infrared galaxy environments (~ 104M⊙ pc-2) so as to map out the scaling of the cloud-scale star formation efficiency (SFE) between these two regimes. The simulations include prescriptions for supernova, stellar wind, and radiative feedback, which we find to be essential in determining both the instantaneous per-freefall (∈ff) and integrated (∈int) star formation efficiencies. In all simulations, the gas discs form stars until a critical stellar surface density has been reached and the remaining gas is blown out by stellar feedback. We find that surface density is a good predictor of ∈int, as suggested by analytic force balance arguments from previous works. SFE eventually saturates to ~ 1 at high surface density. We also find a proportional relationship between ∈ff and ∈int, implying that star formation is feedback-moderated even over very short time-scales in isolated clouds. These results have implications for star formation in galactic discs, the nature and fate of nuclear starbursts, and the formation of bound star clusters. The scaling of ∈ff with surface density is not consistent with the notion that ∈ff is always ~ 1 per cent on the scale of GMCs, but our predictions recover the ~ 1 per cent value for GMC parameters similar to those found in spiral galaxies, including our own.

AB - We present a suite of 3D multiphysics MHD simulations following star formation in isolated turbulent molecular gas discs ranging from 5 to 500 parsecs in radius. These simulations are designed to survey the range of surface densities between those typical of Milky Way giant molecular clouds (GMCs) (~ 102M⊙ pc-2) and extreme ultraluminous infrared galaxy environments (~ 104M⊙ pc-2) so as to map out the scaling of the cloud-scale star formation efficiency (SFE) between these two regimes. The simulations include prescriptions for supernova, stellar wind, and radiative feedback, which we find to be essential in determining both the instantaneous per-freefall (∈ff) and integrated (∈int) star formation efficiencies. In all simulations, the gas discs form stars until a critical stellar surface density has been reached and the remaining gas is blown out by stellar feedback. We find that surface density is a good predictor of ∈int, as suggested by analytic force balance arguments from previous works. SFE eventually saturates to ~ 1 at high surface density. We also find a proportional relationship between ∈ff and ∈int, implying that star formation is feedback-moderated even over very short time-scales in isolated clouds. These results have implications for star formation in galactic discs, the nature and fate of nuclear starbursts, and the formation of bound star clusters. The scaling of ∈ff with surface density is not consistent with the notion that ∈ff is always ~ 1 per cent on the scale of GMCs, but our predictions recover the ~ 1 per cent value for GMC parameters similar to those found in spiral galaxies, including our own.

KW - Galaxies: active

KW - Galaxies: nuclei

KW - Galaxies: star clusters: general

KW - Galaxies: star formation

KW - Galaxies: starburst

UR - http://www.scopus.com/inward/record.url?scp=85045994057&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85045994057&partnerID=8YFLogxK

U2 - 10.1093/MNRAS/STY035

DO - 10.1093/MNRAS/STY035

M3 - Article

AN - SCOPUS:85045994057

SN - 0035-8711

VL - 475

SP - 3511

EP - 3528

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 3

ER -

When feedback fails: The scaling and saturation of star formation efficiency

Abstract

Funding

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this