NanoSIMS isotope studies of rare types of presolar silicon carbide grains from the Murchison meteorite: Implications for supernova models and the role of 14C

Abstract

© 2017 Elsevier Ltd. We have conducted a NanoSIMS ion imaging survey of about 1800 presolar silicon carbide (SiC) grains from the Murchison meteorite. A total of 21 supernova (SN) X grains, two SN C grains, and two putative nova grains were identified. Six particularly interesting grains, two X and C grains each and the two putative nova grains were subsequently studied in greater detail, namely, for C-, N-, Mg-Al-, Si-, S-, and Ca-Ti-isotopic compositions and for the initial presence of radioactive 26 Al (half life 716,000yr), 32 Si (half life 153yr), and 44 Ti (half life 60yr). Their isotope data along with those of three X grains from the literature were compared with model predictions for 15M ⊙ and 25M ⊙ Type II supernovae (SNe). The best fits were found for 25M ⊙ SN models that consider for the He shell the temperature and density of a 15M ⊙ SN and ingestion of H into the He shell before the explosion. In these models a C- and Si-rich zone forms at the bottom of the He burning zone (C/Si zone). The region above the C/Si zone is termed the O/nova zone and exhibits the isotopic fingerprints of explosive H burning. Satisfactory fits of measured C-, N-, and Si-isotopic compositions and of 26 Al/ 27 Al ratios require small-scale mixing of matter originating from a region extending over 0.2M ⊙ for X and C grains and over 0.4M ⊙ for one of the putative nova grains, involving matter from a thin Si-rich layer slightly below the C/Si zone, the C/Si zone, and the O/nova zone. Simultaneous fitting of 14 N/ 15 N and 26 Al/ 27 Al requires a C-N fractionation of a factor of 50 during SiC condensation. This leads to preferential incorporation of radioactive 14 C (half life 5700yr) over directly produced 14 N and can account for the 14 N/ 15 N along with 26 Al/ 27 Al ratios as observed in the SiC grains. The good fit for one of the putative nova grains along with its high 26 Al/ 27 Al points towards a SN origin and supports previous suggestions that some grains classified as nova grains might be from SNe. Apparent problems with the small-scale mixing scheme considered here are C/O ratios that are mostly < 1 if C-, N-, and Si-isotopic compositions and 26 Al/ 27 Al ratios are simultaneously matched, underproduction of 32 Si, and overproduction of 44 Ti. This confirms the limitations of one-dimensional hydrodynamical models for H ingestion and stresses the need to better study the convective-boundary mixing mechanisms at the bottom of the convective He shell in massive star progenitors. This is crucial to define the effective size of the C/Si zone formed by the SN shock. The comparison between the Si isotope data of the SN grains and the models gives a hint that the predicted 30 Si is too high at the bottom of the He burning shell.