High Redshift Supernova Rates
Abstract
We use a sample of 42 supernovae detected with the Advanced Camera for Surveys on-board the Hubble Space Telescope as part of the Great Observatories Origins Deep Survey to measure the rate of core collapse supernovae to z~0.7 and type Ia supernovae to z~1.6. This significantly increases the redshift range where supernova rates have been estimated from observations. The rate of core collapse supernovae can be used as an independent probe of the cosmic star formation rate. Based on the observations of 17 core collapse supernovae, we measure an increase in the core collapse supernova rate by a factor of 1.6 in the range 0.3<z<0.7, and an overall increase by a factor of 7 to z~0.7 in comparison to the local core collapse supernova rate. The increase in the rate in this redshift range in consistent with recent measurements of the star formation rate derived from UV-luminosity densities and IR datasets. Based on 25 type Ia supernovae, we find a SN Ia rate that is a factor 3-5 higher at z~1 compared to earlier estimates at lower redshifts (z<0.5), implying that the type Ia supernova rate traces a higher star formation rate at redshifts z>1 compared to low redshift. At higher redshift (z>1), we find a suggested decrease in the type Ia rate with redshift. This evolution of the Ia rate with redshift is consistent with a type Ia progenitor model where there is a substantial delay between the formation of the progenitor star and the explosion of the supernova. Assuming that the type Ia progenitor stars have initial main sequence masses 3-8 M_Sun, we find that 5-7% of the available progenitors explode as type Ia supernovae.
Cite
@article{arxiv.astro-ph/0406547,
title = {High Redshift Supernova Rates},
author = {Tomas Dahlen and Louis-Gregory Strolger and Adam G. Riess and Bahram Mobasher and Ranga-Ram Chary and Christopher J. Conselice and Henry C. Ferguson and Andrew S. Fruchter and Mauro Giavalisco and Mario Livio and Piero Madau and Nino Panagia and John L. Tonry},
journal= {arXiv preprint arXiv:astro-ph/0406547},
year = {2009}
}
Comments
16 pages, 3 figures, accepted for publication in the Astrophysical Journal