http://arxiv.org/abs/1312.6617
We analyze HST and ground based observations of the luminous Type IIn SN 2010jl from 26 to 1128 days. At maximum the bolometric luminosity was 3×10^{43} erg/s and even at ~ 850 days exceeds 10^{42} erg/s. An emission excess in the NIR, dominating after 400 days, probably originates in dust in the CSM. The observed total radiated energy is at least 6.5×10^{50} ergs. The spectral lines display two distinct components, one broad, due to electron scattering, and one narrow. The broad component is initially symmetric around zero velocity, but becomes blueshifted after ~50 days. We find that dust absorption in the ejecta is unlikely to explain the line shifts, and attribute this instead to radiative acceleration by the SN radiation. From the lines, and the X-ray and dust properties, there is strong evidence for large scale asymmetries in the circumstellar medium. The narrow line component suggests an expansion velocity of ~100 km/s for the CSM. The UV spectrum shows strong low and high ionization lines, while the optical shows a number of narrow coronal lines excited by the X-rays. From the narrow UV lines we find large N/C and N/O ratios, indicative of CNO processing in the progenitor. The luminosity evolution is consistent with a radiative shock in an r^{-2} CSM and indicates a mass loss rate of ~ 0.1 M_O/yr for a 100 km/s wind. The total mass lost is at least ~3 Msun. The mass loss rate, wind velocity, density and CNO enrichment are consistent with the SN expanding into a dense CSM characteristic of that of an LBV progenitor. Even in the last full spectrum at 850 days we do not see any indication of debris processed in a core collapse SN. We attribute this to the extremely dense CSM, which is still opaque to electron scattering. Finally, we discuss the relevance of these UV spectra for detecting Type IIn supernovae in high redshift surveys.
Tue, 24 Dec 13
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