Differences between stellar and laboratory reaction cross sections
نویسنده
چکیده
Nuclear reactions proceed differently in stellar plasmas than in the laboratory due to the thermal effects in the plasma. On one hand, a target nucleus is bombarded by projectiles distributed in energy with a distribution defined by the plasma temperature. The mostly relevant energies are low by nuclear physics standards and thus require an improved description of low-energy properties, such as optical potentials, required for the calculation of reaction cross sections. Recent studies of low-energy cross sections suggest the necessity of a modification of the proton optical potential. On the other hand, target nuclei are in thermal equilibrium with the plasma and this modifies their reaction cross sections. It is generally expected that this modification is larger for endothermic reactions. We show that there is a large number of exceptions to this rule.
منابع مشابه
Astrophysical Rates for Explosive Nucleosynthesis: Stellar and Laboratory Rates for Exotic Nuclei
Nuclear theory is important in the determination of reaction cross sections and rates for astrophysics in several respects. Firstly, a large number of reactions in astrophysical environments involve highly unstable nuclei which are unaccessible in laboratory measurements. This is especially true for the high temperature plasmas of stellar explosions. Secondly, despite of high plasma temperature...
متن کاملStellar enhancement factors in a parity dependent approach
The s-process takes place in stellar environments with temperatures between 8 to 100 keV. In such a plasma the nuclei follow a Maxwell-Boltzmann distribution. Reactions between nucei are characterized by a reaction rate that depends on the temperature of the stellar environment. Reaction rates based on experimental cross sections 〈σv〉 lab do not account for the thermal excitation of the nuclei....
متن کامل- th / 9 61 10 29 v 1 1 4 N ov 1 99 6 Nuclear Astrophysics in Storage Rings
Nuclear reaction cross sections are usually very small in typical astrophysical environments. It has been one of the major challenges of experimental nuclear astrophysics to assess the magnitude of these cross sections in the laboratory. For a successful experiment high luminosity beams are needed. Increasing the target width, one also increases the reaction yields. But, this is of limited use ...
متن کاملuc l - th / 9 60 10 16 v 1 1 2 Ja n 19 96 DELTA DECAY IN NUCLEAR MEDIUM
Proton-nucleus collisions, where the beam proton gets excited to the delta resonance and then decays to pπ + , either inside or outside the nuclear medium, are studied. Cross-sections for various kinematics for the (p,p ′ π +) reaction between 500 MeV and 1 GeV beam energy are calculated to see the effects of the nuclear medium on the propagation and decay of the resonance. The cross-sections s...
متن کاملProton Capture Cross Section of Sr Isotopes and Their Importance for Nucleosynthesis of Proton-rich Nuclides Typeset Using Revt E X 2
The (p,γ) cross sections of three stable Sr isotopes have been measured in the astrophysically relevant energy range. These reactions are important for the p-process in stellar nucleosynthesis and, in addition, the reaction cross sections in the mass region up to 100 are also of importance concerning the rp-process associated with explosive hydrogen and helium burning. It is speculated that thi...
متن کامل