The Universe at <i>z</i> &amp;gt; 10: predictions for <i>JWST</i> from the <scp>universemachine</scp> DR1

Behroozi, Peter; Conroy, Charlie; Wechsler, Risa H.; Hearin, Andrew P.; Williams, Christina C.; Moster, Benjamin P.; Yung, L. Y. Aaron; Somerville, Rachel S.; Gottlöber, Stefan; Yepes, Gustavo; Endsley, Ryan

doi:10.1093/mnras/staa3164

Cited by 106 publications

(118 citation statements)

References 92 publications

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“…Hence the observational data point at = 10.5 falls far below our simulated data, where lower luminosity galaxies are expected to contribute significantly to the star formation rate (e.g. Behroozi et al 2020). In contrast, the data from Ishigaki et al (2018) are integrated to a limiting magnitude of -11 and is much more consistent with our simulations.…”

Section: Impact Of Magnetic Fields On Star Formationsupporting

confidence: 77%

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

Katz

Martin-Alvarez²,

Rosdahl

et al. 2021

Monthly Notices of the Royal Astronomical Society

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We present the first results from SPHINX-MHD, a suite of cosmological radiation-magnetohydrodynamics simulations designed to study the impact of primordial magnetic fields (PMFs) on galaxy formation and the evolution of the intergalactic medium (IGM) during the epoch of reionization. The simulations are among the first to employ multi-frequency, on-the-fly radiation transfer and constrained transport ideal MHD in a cosmological context to simultaneously model the inhomogeneous process of reionization as well as the growth of primordial magnetic fields. We run a series of (5 cMpc)3 cosmological volumes, varying both the strength of the seed magnetic field and its spectral index. We find that PMFs with a spectral index (nB) and a comoving amplitude (B0) that have $n_B > -0.562\log _{10}\left(\frac{B_0}{1{\rm n}G}\right) - 3.35$ produce electron optical depths (τe) that are inconsistent with CMB constraints due to the unrealistically early collapse of low-mass dwarf galaxies. For nB ≥ −2.9, our constraints are considerably tighter than the ∼nG constraints from Planck. PMFs that do not satisfy our constraints have little impact on the reionization history or the shape of the UV luminosity function. Likewise, detecting changes in the Lyα forest due to PMFs will be challenging because photoionisation and photoheating efficiently smooth the density field. However, we find that the first absorption feature in the global 21cm signal is a particularly sensitive indicator of the properties of the PMFs, even for those that satisfy our τe constraint. Furthermore, strong PMFs can marginally increase the escape of LyC photons by up to 25 per cent and shrink the effective radii of galaxies by $\sim 44{{\ \rm per\ cent}}$ which could increase the completeness fraction of galaxy surveys. Finally, our simulations show that surveys with a magnitude limit of ${\rm M_{UV,1500\mathring{\rm A}}=-13}$ can probe the sources that provide the majority of photons for reionization out to z = 12.

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Section: Impact Of Magnetic Fields On Star Formationsupporting

confidence: 77%

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

Katz

Martin-Alvarez²,

Rosdahl

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…The dark matter resolution of ∼ 10 8 M for the Bolshoi-Planck simulation is not ideal for studying the dwarf galaxy regime (M * 10 9 M and M Peak 10 11 M ). The UNIVERSEMACHINE can be run on higher-resolution large-volume cosmological simulations, as was done in Behroozi et al (2020) to predict observables for the JWST, but this approach cannot gain much resolution without an equivalent sacrifice in volume and sample statistics.…”

Section: Introductionmentioning

confidence: 99%

UniverseMachine: Predicting Galaxy Star Formation over Seven Decades of Halo Mass with Zoom-in Simulations

Wang,

Nadler,

Mao

et al. 2021

Preprint

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We apply the empirical galaxy-halo connection model UNIVERSEMACHINE to dark matter-only zoom-in simulations of isolated Milky Way (MW)-mass halos along with their parent cosmological simulations. This application extends UNIVERSEMACHINE predictions into the ultra-faint dwarf galaxy regime (10 2 M M * 10 5 M ) and yields a well-resolved stellar mass-halo mass (SMHM) relation over the peak halo mass range 10 8 M to 10 15 M . The extensive dynamic range provided by the zoom-in simulations allows us to assess specific aspects of dwarf galaxy evolution predicted by UNIVERSEMACHINE. In particular, although UNI-VERSEMACHINE is not constrained for dwarf galaxies with M * 10 8 M , our predicted SMHM relation is consistent with that inferred for MW satellite galaxies at z = 0 using abundance matching. However, UNI-VERSEMACHINE predicts that nearly all galaxies are actively star forming below M * ∼ 10 7 M and that these systems typically form more than half of their stars at z 4, which is discrepant with the star formation histories of Local Group dwarf galaxies that favor early quenching. This indicates that the current UNIVERSEMACHINE model does not fully capture galaxy quenching physics at the low-mass end. We highlight specific improvements necessary to incorporate environmental and reionization-driven quenching for dwarf galaxies, and provide a new tool to connect dark matter accretion to star formation over the full dynamic range that hosts galaxies.

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“…Theoretical predictions indicate that MBHs seeds from remnants of PopIII stars could form at redshifts as high as 20 (Volonteri 2010;Inayoshi et al 2020), while redshifts considered for DCBHs fall approximately between 13 and 20 (Yue et al 2014). This is outside the range of any of current EM observatories, however future missions like SKA in radio (Taylor 2000), JWST in IR/optical (Behroozi et al 2020) and Athena in X-rays (Nandra et al 2013) will probe sources up to redshifts of about 15-20.…”

Section: Introductionmentioning

confidence: 98%

Predictions for LISA and PTA based on SHARK galaxy simulations

Curyło,

Bulik

2021

Preprint

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We present our analysis of a set of populations of massive black hole binaries generated in the recent semi-analytic model of galaxy evolution (SHARK). We focus on studying gravitational wave emission produced by these inspiraling binaries in terms of their detectability with current and future detectors, i.e. PTA (Pulsar Timing Array) and LISA (Laser Interferometer Space Antenna). The key advantage of SHARK is that it provides a way to explore a number of distinct models of black hole and galaxy evolution processes within a consistent framework and it was also successfully tested against EM observational data. In our work, we study 12 models varying in seed formation scenarios and test two different BH growth and feedback models. We show that all of the models fit well within current observational constraints on GWB and BH mass functions and that complementary LISA and PTA detections will be able improve our understanding of MBH and galaxy co-evolution processes.

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The Universe at z > 10: predictions for JWST from the universemachine DR1

Cited by 106 publications

References 92 publications

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

UniverseMachine: Predicting Galaxy Star Formation over Seven Decades of Halo Mass with Zoom-in Simulations

Predictions for LISA and PTA based on SHARK galaxy simulations

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The Universe at z &gt; 10: predictions for JWST from the universemachine DR1

Cited by 106 publications

References 92 publications

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

Introducing SPHINX-MHD: the impact of primordial magnetic fields on the first galaxies, reionization, and the global 21-cm signal

UniverseMachine: Predicting Galaxy Star Formation over Seven Decades of Halo Mass with Zoom-in Simulations

Predictions for LISA and PTA based on SHARK galaxy simulations

Contact Info

Product

Resources

About

The Universe at z > 10: predictions for JWST from the universemachine DR1