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MS: Fachverband Massenspektrometrie

MS 13: Accelerator Mass Spectrometry and Applications 3

MS 13.2: Vortrag

Donnerstag, 26. März 2015, 17:30–17:45, PH/HS2

Supernova-Produced ²⁶Al and ⁶⁰Fe in Deep-Sea Sediments — •Jenny Feige¹, Anton Wallner², L. Keith Fifield², Silke Merchel³, Georg Rugel³, Peter Steier¹, Steve Tims², Stephan R. Winkler¹, and Robin Golser¹ — ¹University of Vienna, Austria — ²ANU Canberra, Australia — ³HZDR, Germany

Massive stars, which end their lives in a supernova (SN) explosion, eject freshly produced nuclides into the surrounding interstellar medium. Among them long-lived radionuclides, that can be deposited into terrestrial archives, if such an event occurs close to the Solar System.

About 100 samples of four deep-sea sediment cores originating from the Indian Ocean were analyzed for their content in the isotopes ²⁶Al and ⁶⁰Fe for the time range of 2-3 Myr. These nuclides are produced in SNe and the time range corresponds to an ⁶⁰Fe enhancement observed in a deep-ocean crust sample (Knie et al., 2004). The method used for analysis is accelerator mass spectrometry (AMS), a very sensitive technique for the detection of long-lived radionuclides.

A clear signal of ⁶⁰Fe throughout the whole measured time period was observed. This observation is in contrast to a narrow peak if originating from a direct input from a single SN. Further, no ⁶⁰Fe was detected in much older or younger sediment samples. A concurring SN-signal of ²⁶Al is, however, hidden underneath a dominant terrestrial background from continuous atmospheric and in-situ production. The resulting limits on the ratios of ⁶⁰Fe/²⁶Al were compared to nucleosynthesis models.