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Revised rates for the stellar triple-alpha process from measurement of 12C nuclear resonances
Authors:Fynbo Hans O U  Diget Christian A A  Bergmann Uffe C  Borge Maria J G  Cederkäll Joakim  Dendooven Peter  Fraile Luis M  Franchoo Serge  Fedosseev Valentin N  Fulton Brian R  Huang Wenxue  Huikari Jussi  Jeppesen Henrik B  Jokinen Ari S  Jones Peter  Jonson Björn  Köster Ulli  Langanke Karlheinz  Meister Mikael  Nilsson Thomas  Nyman Göran  Prezado Yolanda  Riisager Karsten  Rinta-Antila Sami  Tengblad Olof  Turrion Manuela  Wang Youbao  Weissman Leonid  Wilhelmsen Katarina  Aystö Juha;ISOLDE Collaboration
Institution:Department of Physics and Astronomy, University of Aarhus, 8000 Arhus C, Denmark. fynbo@phys.au.dk
Abstract:In the centres of stars where the temperature is high enough, three alpha-particles (helium nuclei) are able to combine to form 12C because of a resonant reaction leading to a nuclear excited state. (Stars with masses greater than approximately 0.5 times that of the Sun will at some point in their lives have a central temperature high enough for this reaction to proceed.) Although the reaction rate is of critical significance for determining elemental abundances in the Universe, and for determining the size of the iron core of a star just before it goes supernova, it has hitherto been insufficiently determined. Here we report a measurement of the inverse process, where a 12C nucleus decays to three alpha-particles. We find a dominant resonance at an energy of approximately 11 MeV, but do not confirm the presence of a resonance at 9.1 MeV (ref. 3). We show that interference between two resonances has important effects on our measured spectrum. Using these data, we calculate the triple-alpha rate for temperatures from 10(7) K to 10(10) K and find significant deviations from the standard rates. Our rate below approximately 5 x 10(7) K is higher than the previous standard, implying that the critical amounts of carbon that catalysed hydrogen burning in the first stars are produced twice as fast as previously believed. At temperatures above 10(9) K, our rate is much less, which modifies predicted nucleosynthesis in supernovae.
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