A nearby supernova (SN) explosion in the past can be confirmed by the detection of radioisotopes on Earth that were produced and ejected by the SN. We have now measured a well resolved time profile of the 60Fe concentration in a deep-sea ferromanganese crust and found a highly significant increase 2.8 Myr ago. The amount of 60Fe is compatible with the deposition of ejecta from a SN at a distance of a few 10 pc. The well defined time of the SN explosion makes it possible to search for plausible correlations with other events in Earth's history.
We report the direct measurement of the 7 Be solar neutrino signal rate performed with the Borexino detector at the Laboratori Nazionali del Gran Sasso. The interaction rate of the 0.862 MeV 7 Be neutrinos is 49±3stat±4syst counts/(day·100 ton). The hypothesis of no oscillation for 7 Be solar neutrinos is inconsistent with our measurement at the 4σ C.L.. Our result is the first direct measurement of the survival probability for solar νe in the transition region between matter-enhanced and vacuum-driven oscillations. The measurement improves the experimental determination of the flux of 7 Be, pp, and CNO solar νe, and the limit on the magnetic moment of neutrinos.PACS numbers: 13.35. Hb, 14.60.St, 26.65.+t, 95.55.Vj, 29.40.Mc Neutrino oscillations [1] are the established mechanism to explain the solar neutrino problem, which originated from observations in radiochemical experiments with a sub-MeV threshold [2,3] and from real time observation of high energy neutrinos [4,5]. Neutrino oscillations were also observed in atmospheric neutrinos [4] and have been confirmed with observation of reactorν e [6]. Borexino is the first experiment to report a real-time observation arXiv:0805.3843v2 [astro-ph]
Half of the heavy elements including all actinides are produced in r-process
nucleosynthesis, whose sites and history remain a mystery. If continuously produced,
the Interstellar Medium is expected to build-up a quasi-steady state of abundances
of short-lived nuclides (with half-lives ≤100 My), including actinides
produced in r-process nucleosynthesis. Their existence in today’s
interstellar medium would serve as a radioactive clock and would establish that
their production was recent. In particular 244Pu, a radioactive
actinide nuclide (half-life=81 My), can place strong constraints on recent
r-process frequency and production yield. Here we report the detection of
live interstellar 244Pu, archived in Earth’s deep-sea
floor during the last 25 My, at abundances lower than expected from continuous
production in the Galaxy by about 2 orders of magnitude. This large discrepancy may
signal a rarity of actinide r-process nucleosynthesis sites, compatible with
neutron-star mergers or with a small subset of actinide-producing supernovae.
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