The time-scales probed by star formation rate indicators for realistic, bursty star formation histories from the FIRE simulations

Creators: Flores Velázquez, José A.; Gurvich, Alexander B.; Faucher-Giguère, Claude-André; Bullock, James S.; Starkenburg, Tjitske K.; Moreno, Jorge; Lazar, Alexandres; Mercado, Francisco J.; Stern, Jonathan; Sparre, Martin; Hayward, Christopher C.; Wetzel, Andrew; El-Badry, Kareem

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Abstract

Understanding the rate at which stars form is central to studies of galaxy formation. Observationally, the star formation rates (SFRs) of galaxies are measured using the luminosity in different frequency bands, often under the assumption of a time-steady SFR in the recent past. We use star formation histories (SFHs) extracted from cosmological simulations of star-forming galaxies from the FIRE project to analyse the time-scales to which the H α and far-ultraviolet (FUV) continuum SFR indicators are sensitive. In these simulations, the SFRs are highly time variable for all galaxies at high redshift, and continue to be bursty to z = 0 in dwarf galaxies. When FIRE SFHs are partitioned into their bursty and time-steady phases, the best-fitting FUV time-scale fluctuates from its ∼10 Myr value when the SFR is time-steady to ≳100 Myr immediately following particularly extreme bursts of star formation during the bursty phase. On the other hand, the best-fitting averaging time-scale for H α is generally insensitive to the SFR variability in the FIRE simulations and remains ∼5 Myr at all times. These time-scales are shorter than the 100 and 10 Myr time-scales sometimes assumed in the literature for FUV and H α, respectively, because while the FUV emission persists for stellar populations older than 100 Myr, the time-dependent luminosities are strongly dominated by younger stars. Our results confirm that the ratio of SFRs inferred using H α versus FUV can be used to probe the burstiness of star formation in galaxies.

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© 2020 The Author(s). Published by Oxford University Press on behalf of Royal Astronomical Society. This article is published and distributed under the terms of the Oxford University Press, Standard Journals Publication Model (https://academic.oup.com/journals/pages/open_access/funder_policies/chorus/standard_publication_model). This paper represents the effort of José Antonio Flores Velázquez, whose life was tragically taken on 2019 August 14 before he could see this project finished. José was a beloved son, brother, friend, and colleague, with a warm smile and a big heart. Those who knew him were inspired by his unwavering optimism and passion for his work. On top of being a great person, he was also a remarkably talented astronomer, with great potential as exemplified by his drive to learn things by himself while also recognizing when to reach out for help. His refusal to sacrifice his identity also made, and continues to make, him a role model to folks who struggle to embody their culture in academic settings. The field of Astronomy lost a brilliant scientist and our goal is to share his work with the community. The authors thank the anonymous referee for their careful review of this manuscript. JAFV was supported by a National Science Foundation Graduate Research Fellowship Program under grant DGE-1839285. ABG was also supported by an NSF-GRFP under grant DGE-1842165 and was additionally supported by NSF grants DGE-0948017 and DGE-145000. CAFG was supported by NSF through grants AST-1412836, AST-1517491, AST-1715216, and CAREER award AST1652522, by NASA through grants NNX15AB22G and 17-ATP17-0067, by STScI through grants HST-GO-14681.011, HST-GO-14268.022-A, and HST-AR-14293.001-A, and by a Cottrell Scholar Award from the Research Corporation for Science Advancement. JSB, AL, and FJM were supported by NSF grants AST-1910346 and AST-1518291. Support for JM is provided by the NSF (AST Award Number 1516374), and by the Harvard Institute for Theory and Computation, through their Visiting Scholars Program. JS is supported as a CIERA Fellows by the CIERA Postdoctoral Fellowship Program (Center for Interdisciplinary Exploration and Research in Astrophysics, Northwestern University). AW received support from NASA through ATP grant 80NSSC18K1097 and HST grants GO-14734, AR-15057, AR-15809, and GO-15902 from STScI; the Heising-Simons Foundation; and a Hellman Fellowship. KE was supported by an NSF-GRFP and a Hellman fellowship from UC Berkeley. The Flatiron Institute is supported by the Simons Foundation. Numerical calculations were run on the Quest computing cluster at Northwestern University, the Wheeler computing cluster at Caltech, XSEDE allocations TG-AST130039, TG-AST120025, and TG-AST140023, Blue Waters PRAC allocation NSF.1713353, and NASA HEC allocations SMD16-7592, SMD-16-7561 and SMD-17-1204. We honour the invaluable labour of the maintenance and clerical staff at our institutions, whose contributions make our scientific discoveries a reality. This research was conducted on Potawatomi Indigenous land. DATA AVAILABILITY. The data supporting the plots within this article are available on reasonable request to the corresponding author. A public version of the gizmo code is available at http://www.tapir.caltech.edu/~phopkins/Site/GIZMO.html. Additional data including simulation snapshots, initial conditions, and derived data products are available at http://fire.northwestern.edu/data/.

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Resource type: Journal Article
Publisher: Royal Astronomical Society
Published in: Monthly Notices of the Royal Astronomical Society, 501(4), 4812-4824, ISSN: 0035-8711.