Your search keyword '"L. Crespo Campo"' showing total 2 results

1. Low-energy enhancement and fluctuations of γ-ray strength functions in 56,57Fe: test of the Brink–Axel hypothesis.

Author

A C Larsen, M Guttormsen, N Blasi, A Bracco, F Camera, L Crespo Campo, T K Eriksen, A Görgen, T W Hagen, V W Ingeberg, B V Kheswa, S Leoni, J E Midtbø, B Million, H T Nyhus, T Renstrøm, S J Rose, I E Ruud, S Siem, and T G Tornyi

Subjects

*ENERGY level densities, *IRON isotopes, *FLUCTUATIONS (Physics), *STRENGTH of materials, *PROTONS, *ANGULAR distribution (Nuclear physics)

Abstract

Nuclear level densities and γ-ray strength functions of 56,57Fe have been extracted from proton-γ coincidences. A low-energy enhancement in the γ-ray strength functions up to a factor of 30 over common theoretical E1 models is confirmed. Angular distributions of the low-energy enhancement in 57Fe indicate its dipole nature, in agreement with findings for 56Fe. The high statistics and the excellent energy resolution of the large-volume LaBr3(Ce) detectors allowed for a thorough analysis of γ strength as function of excitation energy. Taking into account the presence of strong Porter–Thomas fluctuations, there is no indication of any significant excitation energy dependence in the γ-ray strength function, in support of the generalized Brink–Axel hypothesis. [ABSTRACT FROM AUTHOR]

Published

2017

2. Neutron-capture rates for explosive nucleosynthesis: the case of 68Ni(n, γ)69Ni.

Author

A Spyrou, A C Larsen, S N Liddick, F Naqvi, B P Crider, A C Dombos, M Guttormsen, D L Bleuel, A Couture, L Crespo Campo, R Lewis, S Mosby, M R Mumpower, G Perdikakis, C J Prokop, S J Quinn, T Renstrøm, S Siem, and R Surman

Subjects

*NUCLEAR reactions, *NUCLEOSYNTHESIS, *NUCLEAR density, *EXCITED states, *NEUTRON capture, *NUMERICAL calculations

Abstract

Neutron-capture reactions play an important role in heavy element nucleosynthesis, since they are the driving force for the two processes that create the vast majority of the heavy elements. When a neutron capture occurs on a short-lived nucleus, it is extremely challenging to study the reaction directly and therefore the use of indirect techniques is essential. The present work reports on such an indirect measurement that provides strong constraints on the 68Ni(n, γ)69Ni reaction rate. This is done by populating the compound nucleus 69Ni via the β decay of 69Co and measuring the γ-ray deexcitation of excited states in 69Ni. The β-Oslo method was used to extract the γ-ray strength function and the nuclear level density. In addition the half-life of 69Co was extracted and found to be in agreement with previous literature values. Before the present results, the 68Ni(n, γ)69Ni reaction was unconstrained and the purely theoretical reaction rate was highly uncertain. The new uncertainty on the reaction rate based on the present experiment (variation between upper and lower limit) is approximately a factor of 3. The commonly used reaction libraries JINA-REACLIB and BRUSLIB are in relatively good agreement with the experimental rate. The impact of the new rate on weak r-process calculations is discussed. [ABSTRACT FROM AUTHOR]

Published

2017