Ivan K. Baldry
The 2dF Galaxy Redshift Survey: Constraints on Cosmic Star Formation History from the Cosmic Spectrum.
Baldry, Ivan K.; Glazebrook, Karl; Baugh, Carlton M.; Bland-Hawthorn, Joss; Bridges, Terry; Cannon, Russell; Cole, Shaun; Colless, Matthew; Collins, Chris; Couch, Warrick; Dalton, Gavin; De Propris, Roberto; Driver, Simon P.; Efstathiou, George; Ellis, Richard S.; Frenk, Carlos S.; Hawkins, Edward; Jackson, Carole; Lahav, Ofer; Lewis, Ian; Lumsden, Stuart; Maddox, Steve; Madgwick, Darren S.; Norberg, Peder; Peacock, John A.; Peterson, Bruce A.; Sutherland, Will; Taylor, Keith
Authors
Karl Glazebrook
Professor Carlton Baugh c.m.baugh@durham.ac.uk
Professor
Joss Bland-Hawthorn
Terry Bridges
Russell Cannon
Professor Shaun Cole shaun.cole@durham.ac.uk
Director of the Institute for Computational Cosmology
Matthew Colless
Chris Collins
Warrick Couch
Gavin Dalton
Roberto De Propris
Simon P. Driver
George Efstathiou
Richard S. Ellis
Professor Carlos Frenk c.s.frenk@durham.ac.uk
Professor
Edward Hawkins
Carole Jackson
Ofer Lahav
Ian Lewis
Stuart Lumsden
Steve Maddox
Darren S. Madgwick
Professor Peder Norberg peder.norberg@durham.ac.uk
Professor
John A. Peacock
Bruce A. Peterson
Will Sutherland
Keith Taylor
Abstract
We present the first results on the history of star formation in the universe based on the "cosmic spectrum," in particular the volume-averaged, luminosity-weighted, stellar absorption-line spectrum of present-day galaxies from the 2dF Galaxy Redshift Survey. This method is novel in that, unlike previous studies, it is not an estimator based on total luminosity density. The cosmic spectrum is fitted with models of population synthesis, tracing the history of star formation before the epoch of the observed galaxies, using a method we have developed that decouples continuum and spectral line variations and is robust against spectrophotometric uncertainties. The cosmic spectrum can only be fitted with models incorporating chemical evolution, and it indicates that there was a peak in the star formation rate (SFR) in the past of at least 3 times the current value and that the increase back to z = 1, assuming it scales as (1 + z)β, has a strong upper limit of β < 5. We find, in the general case, that there is some model degeneracy between star formation at low and high redshift. However, if we incorporate previous work on star formation at z < 1, we can put strong upper limits on the star formation rate at z > 1: e.g., if β > 2, then the SFR for 1 < z < 5 scales as (1 + z)α, with α < 2. This is equivalent to stating that no more than 80% of stars in the universe formed at z > 1. Our results are consistent with the best-fit results from compilations of cosmic SFR estimates based on UV luminosity density, which yield 1.8 < β < 2.9 and -1.0 < α < 0.7, and are also consistent with estimates of Ωstars based on the K-band luminosity density.
Citation
Baldry, I. K., Glazebrook, K., Baugh, C. M., Bland-Hawthorn, J., Bridges, T., Cannon, R., …Taylor, K. (2002). The 2dF Galaxy Redshift Survey: Constraints on Cosmic Star Formation History from the Cosmic Spectrum. Astrophysical Journal, 569(2), 582-594. https://doi.org/10.1086/339477
| Journal Article Type | Article |
|---|---|
| Acceptance Date | Jan 3, 2002 |
| Publication Date | 2002-04 |
| Journal | Astrophysical Journal |
| Print ISSN | 0004-637X |
| Electronic ISSN | 1538-4357 |
| Publisher | American Astronomical Society |
| Peer Reviewed | Peer Reviewed |
| Volume | 569 |
| Issue | 2 |
| Pages | 582-594 |
| DOI | https://doi.org/10.1086/339477 |
| Public URL | https://durham-repository.worktribe.com/output/1607549 |
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