Gy. Gyürky scite author profile

Abstract. A small number of naturally occurring, proton-rich nuclides (the p-nuclei) cannot be made in the s-and r-process. Their origin is not well understood. Massive stars can produce p-nuclei through photodisintegration of pre-existing intermediate and heavy nuclei. This so-called γ-process requires high stellar plasma temperatures and occurs mainly in explosive O/Ne burning during a core-collapse supernova. Although the γ-process in massive stars has been successful in producing a large range of p-nuclei, significant deficiences remain. An increasing number of processes and sites has been studied in recent years in search of viable alternatives replacing or supplementing the massive star models. A large number of unstable nuclei, however, with only theoretically predicted reaction rates are included in the reaction network and thus the nuclear input may also bear considerable uncertainties. The current status of astrophysical models, nuclear input, and observational constraints is reviewed. After an overview of currently discussed models, the focus is on the possibility to better constrain those models through different means. Meteoritic data not only provide the actual isotopic abundances of the p-nuclei but can also put constraints on the possible contribution of proton-rich nucleosynthesis. The main part of the review focusses on the nuclear uncertainties involved in the determination of the astrophysical reaction rates required for the extended reaction networks used in nucleosynthesis studies. Experimental approaches are discussed together with their necessary connection to theory, which is especially pronounced for reactions with intermediate and heavy nuclei in explosive nuclear burning, even close to stability.

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Astrophysical S-factor of 14N(p,γ)15O

Formicola

et al. 2004

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We report on a new measurement of the 14N(p,γ)15O capture cross section at Ep=140 to 400 keV using the 400 kV LUNA accelerator facility at the Laboratori Nazionali del Gran Sasso (LNGS). The uncertainties have been reduced with respect to previous measurements and their analysis. We have analyzed the data using the R-matrix method and we find that the ground state transition accounts for about 15% of the total S-factor. The main contribution to the S-factor is given by the transition to the 6.79 MeV state. We find a total S(0)=1.7+/-0.2 keVb, in agreement with recent extrapolations. The result has important consequences for the solar neutrino spectrum as well as for the age of globular clusters

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S-factor of 14N(p,γ)15O at astrophysical energies⋆

et al. 2005

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Abstract. The astrophysical S(E) factor of14 N(p, γ) 15 O has been measured for effective center-of-mass energies between E ef f = 119 and 367 keV at the LUNA facility using TiN solid targets and Ge detectors. The data are in good agreement with previous and recent work at overlapping energies. R-matrix analysis reveals that due to the complex level structure of 15 O the extrapolated S(0) value is model dependent and calls for additional experimental efforts to reduce the present uncertainty in S(0) to a level of a few percent as required by astrophysical calculations. .KvX -and γ ray spectroscopy -97.10.CvStellar structure and evolution PACS

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The baryon density of the Universe from an improved rate of deuterium burning

Mossa

Stöckel

Cavanna

et al. 2020

Nature

166

254

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Erratum: Stellar and Primordial Nucleosynthesis ofBe7: Measurement ofHe3(α,<

Leva¹,

Gialanella²,

Kunz³

et al. 2009

Phys. Rev. Lett.

198

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Gy. Gyürky

Constraining the astrophysical origin of the p-nuclei through nuclear physics and meteoritic data

Astrophysical S-factor of 14N(p,γ)15O

S-factor of 14N(p,γ)15O at astrophysical energies⋆

The baryon density of the Universe from an improved rate of deuterium burning

Erratum: Stellar and Primordial Nucleosynthesis ofBe7: Measurement ofHe3(α,<

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