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HK: Fachverband Hadronen und Kerne
HK 50: Nuclear Astrophysics
HK 50.1: Gruppenbericht
Mittwoch, 18. März 2009, 14:00–14:30, H-ZO 60
The 12C+12C fusion reactions at astrophysical energies — •Frank Strieder1, Hans-Werner Becker1, Nicola DeCesare2, Antonino Di Leva1,2, Antonio D’Onofrio2, Lucio Gialanella2, Benedetta Limata2, Claus Rolfs1, Jeff Schweitzer3, Tim Spillane3, Oscar Straniero4, Filippo Terrasi2, and Jim Zickefoose3 — 1Ruhr-Universität Bochum, Germany — 2INFN Napoli, Italy — 3University of Connecticut, USA — 4Osservatorio Astronomico di Teramo, Italy
The fusion reactions 12C(12C,α)20Ne and 12C(12C,p)23Na are referred to as carbon burning in stars. In massive stars the ashes produced during helium burning become the fuel for further nuclear-burning processes, leading to the synthesis of most elements with mass numbers larger than 20. Consequently, these fusion reactions represent key processes since they influence not only the nucleosynthesis but also the subsequent evolution of a star. However, at the astrophysical relevant energies the reaction rate of these fusion reactions is not very well known and provided only by extrapolations of high energy data. The reactions have now been studied from E = 1.5 to 4.75 MeV by γ-ray and particle spectroscopy using thick carbon targets. The data reveal new resonances, in particular strong resonances at E<2.3 MeV, which lie in the range of the Gamow peak for carbon burning in massive stars, which takes place at temperatures T ≈ (5−10)×108 K. These resonances increase the present reaction rate significantly in this temperature range. The impact of the results on various astrophysical sites, e.g. supernovae progenitor stars, will be discussed.