Astrophys.J.641:1039-1050,2006 We present u'g'r'i'BV photometry and optical spectroscopy of the Type Ib/Ic
SN 2005bf covering the first ~100 days following discovery. The u'g'BV light
curves ...displayed a double-peaked morphology, which is among Type Ib/Ic
supernovae. The bolometric light curve indicates that SN 2005bf was a
remarkably luminous event. Spectroscopically, SN 2005bf underwent a unique
transformation from a Type Ic-like event at early times to a typical Type Ib
supernova at later phases. The initial maximum in u'g'BV was accompanied by the
presence in the spectrum of high velocity absorption lines of Fe II, Ca II, and
H I. The photospheric velocity derived from spectra at early epochs was
unusually low compared with ordinary Type Ib supernovae. We describe
one-dimensional computer simulations which attempt to account for these
remarkable properties. The most favored model is that of a very energetic (2 x
10^{51} erg), asymmetric explosion of a massive (8.3 M_sun) Wolf-Rayet WN star
that had lost most of its hydrogen envelope. We speculate that an unobserved
relativistic jet was launched producing a two-component explosion consisting of
1) a polar explosion containing a small fraction of the total mass and moving
at high velocity, and 2) the explosion of the rest of the star. At first, only
the polar explosion is observed, producing the initial maximum and the high
velocity absorption-line spectrum resembling a Type Ic event. At late times,
this fast-moving component becomes optically-thin, revealing the slower-moving
explosion of the rest of the star and transforming the observed spectrum to
that of a typical Type Ib supernova. If this scenario is correct, then SN
2005bf is the best example to date of a transition object between normal Type
Ib/Ic supernovae and gamma ray bursts.
A type Ia supernova (SN Ia), one of the two main classes of exploding stars, is recognized by the absence of hydrogen and the presence of elements such as silicon and sulphur in its spectra. These ...explosions are thought to produce the majority of iron-peak elements in the universe and are known to be precise "standard candles" used to measure distances to galaxies. While there is general agreement that SNe Ia are exploding white dwarfs, astronomers face the embarassing problem that the progenitor systems have never been directly observed. Significant effort has been put into the detection of circum-stellar material (CSM) in order to discriminate between the different types of possible progenitors systems, yet no CSM has been found. Here we report optical observations of SN 2002ic which reveal large amounts of CSM seen as a strong hydrogen emission. This observation suggests that the progenitor system contained a massive asymptotic branch giant star which lost a few solar masses of hydrogen-rich gas prior to the type Ia explosion.
We present u'g'r'i'BV photometry and optical spectroscopy of the Type Ib/Ic SN 2005bf covering the first ~100 days following discovery. The u'g'BV light curves displayed a double-peaked morphology, ...which is among Type Ib/Ic supernovae. The bolometric light curve indicates that SN 2005bf was a remarkably luminous event. Spectroscopically, SN 2005bf underwent a unique transformation from a Type Ic-like event at early times to a typical Type Ib supernova at later phases. The initial maximum in u'g'BV was accompanied by the presence in the spectrum of high velocity absorption lines of Fe II, Ca II, and H I. The photospheric velocity derived from spectra at early epochs was unusually low compared with ordinary Type Ib supernovae. We describe one-dimensional computer simulations which attempt to account for these remarkable properties. The most favored model is that of a very energetic (2 x 10^{51} erg), asymmetric explosion of a massive (8.3 M_sun) Wolf-Rayet WN star that had lost most of its hydrogen envelope. We speculate that an unobserved relativistic jet was launched producing a two-component explosion consisting of 1) a polar explosion containing a small fraction of the total mass and moving at high velocity, and 2) the explosion of the rest of the star. At first, only the polar explosion is observed, producing the initial maximum and the high velocity absorption-line spectrum resembling a Type Ic event. At late times, this fast-moving component becomes optically-thin, revealing the slower-moving explosion of the rest of the star and transforming the observed spectrum to that of a typical Type Ib supernova. If this scenario is correct, then SN 2005bf is the best example to date of a transition object between normal Type Ib/Ic supernovae and gamma ray bursts.