Add to ORKGCarbon burning plays a crucial role in stellar evolution, where this reaction is an important route for the production of heavier elements. A particle-γ coincidence technique that minimizes the backgrounds to which this reaction is subject and provides reliable cross sections has been used at the Argonne National Laboratory to measure fusion cross-sections at deep sub-barrier energies in the 12C+12C system. The corresponding excitation function has been extracted down to a cross section of about 6 nb. This indicates the existence of a broad S-factor maximum for this system. Experimental results are presented and discussed
International audienceCarbon burning is a critical phase for nucleosynthesis in massive stars. The c...
Context. By changing the internal composition of stars, nuclear reactions play a key role in their e...
The C12+C12 fusion reaction plays a critical role in the evolution of massive stars and also strongl...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
The 12C + 12C fusion reaction is one of the most important reactions in the stellar evolution. Due t...
The C12+C12 fusion reaction plays a critical role in the evolution of massive stars and also strongl...
Carbon burning takes place in stars at deep sub-Coulomb energies through the 12C(12C,α)20Ne and 12C(...
The 12C+12C fusion reaction is one of the most important for nuclear astrophysics since it determine...
International audienceCarbon burning is a critical phase for nucleosynthesis in massive stars. The c...
Context. By changing the internal composition of stars, nuclear reactions play a key role in their e...
The C12+C12 fusion reaction plays a critical role in the evolution of massive stars and also strongl...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning plays a crucial role in stellar evolution, where this reaction is an important route ...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
Carbon burning is a critical phase for nucleosynthesis in massive stars. The conditions for igniting...
The 12C + 12C fusion reaction is one of the most important reactions in the stellar evolution. Due t...
The C12+C12 fusion reaction plays a critical role in the evolution of massive stars and also strongl...
Carbon burning takes place in stars at deep sub-Coulomb energies through the 12C(12C,α)20Ne and 12C(...
The 12C+12C fusion reaction is one of the most important for nuclear astrophysics since it determine...
International audienceCarbon burning is a critical phase for nucleosynthesis in massive stars. The c...
Context. By changing the internal composition of stars, nuclear reactions play a key role in their e...
The C12+C12 fusion reaction plays a critical role in the evolution of massive stars and also strongl...