The Extended Hubble Space Telescope Supernova Survey: The Rate of Core Collapse Supernovae to z~1

TL;DR

This study measures the rate of core collapse supernovae up to redshift 1, using Hubble Space Telescope data, and discusses the importance of systematic errors like dust extinction in these measurements.

Contribution

The paper provides new measurements of core collapse supernova rates up to z~1, including corrections for dust extinction and an analysis of systematic uncertainties.

Findings

Supernova rates increase with redshift up to z~1.

Corrected for host galaxy dust extinction.

Good agreement with star formation rate-based predictions.

Abstract

We use a sample of 45 core collapse supernovae detected with the Advanced Camera for Surveys on-board the Hubble Space Telescope to derive the core collapse supernova rate in the redshift range 0.1<z<1.3. In redshift bins centered on <z>=0.39, <z>=0.73, and <z>=1.11, we find rates 3.00 {+1.28}{-0.94}{+1.04}{-0.57}, 7.39 {+1.86}{-1.52}{+3.20}{-1.60}, and 9.57 {+3.76}{-2.80}{+4.96}{-2.80}, respectively, given in units yr^{-1} Mpc^{-3} 10^{-4} h_{70}^3. The rates have been corrected for host galaxy extinction, including supernovae missed in highly dust enshrouded environments in infrared bright galaxies. The first errors represent statistical while the second are the estimated systematic errors. We perform a detailed discussion of possible sources of systematic errors and note that these start to dominate over statistical errors at z>0.5, emphasizing the need to better control the systematic effects. For example, a better understanding of the amount of dust extinction in the host galaxies and knowledge of the supernova luminosity function, in particular the fraction of faint M > -15 supernovae, is needed to better constrain the rates. When comparing our results with the core collapse supernova rate based on the star formation rate, we find a good agreement, consistent with the supernova rate following the star formation rate, as expected.