The rise-time of Type II supernovae
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Abstract
We investigate the early-time light curves of a large sample of 223 Type II supernovae
(SNe II) from the Sloan Digital Sky Survey and the Supernova Legacy Survey. Having a
cadence of a few days and sufficient non-detections prior to explosion, we constrain risetimes,
i.e. the durations from estimated first to maximum light, as a function of effective
wavelength. At rest-frame g band (λeff = 4722 Å), we find a distribution of fast rise-times
with median of (7.5 ± 0.3) d. Comparing these durations with analytical shock models of
Rabinak & Waxman and Nakar & Sari, and hydrodynamical models of Tominaga et al., which
are mostly sensitive to progenitor radius at these epochs, we find a median characteristic
radius of less than 400 solar radii. The inferred radii are on average much smaller than the
radii obtained for observed red supergiants (RSG). Investigating the post-maximum slopes
as a function of effective wavelength in the light of theoretical models, we find that massive
hydrogen envelopes are still needed to explain the plateaus of SNe II. We therefore argue
that the SN II rise-times we observe are either (a) the shock cooling resulting from the core
collapse of RSG with small and dense envelopes, or (b) the delayed and prolonged shock
breakout of the collapse of an RSG with an extended atmosphere or embedded within pre-SN
circumstellar material.
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Artículo de publicación ISI
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MNRAS 451, 2212–2229 (2015)
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