Gamma-ray lines from SN2014J

Abstract

On 21 January 2014, SN2014J was discovered in M82 and found to be the closest type Ia supernova (SN Ia) in the last four decades. INTEGRAL observed SN2014J from the end of January until late June for a total exposure time of about 7 Ms. SNe Ia light curves are understood to be powered by the radioactive decay of iron peak elements of which 56Ni is dominantly synthesized during the thermonuclear disruption of a CO white dwarf (WD). The measurement of γ-ray lines from the decay chain 56Ni→56Co→56Fe provides unique information about the explosion in supernovae. Canonical models assume 56Ni buried deeply in the supernova cloud, absorbing most of the early γ-rays, and only the consecutive decay of 56Co should become directly observable through the overlaying material several weeks after the explosion when the supernova envelope dilutes as it expands. Surprisingly, with the spectrometer on INTEGRAL, SPI, we detected 56Ni γ-ray lines at 158 and 812 keV at early times with flux levels corresponding to roughly 10% of the total expected amount of 56Ni, and at relatively small velocities. This implies some mechanism to create a major amout of 56Ni at the outskirts, and at the same time to break the spherical symmetry of the supernova. One plausible explanation would be a belt accreted from a He companion star, exploding, and triggering the explosion of the white dwarf. The full set of observations of SN2014J show 56Co γ-ray lines at 847 and 1238 keV, and we determine for the first time a SN Ia γ-ray light curve. The irregular appearance of these γ-ray lines allows deeper insights about the explosion morphology from its temporal evolution and provides additional evidence for an asymmetric explosion, from our high-resolution spectroscopy and comparisons with recent models.