2013
DOI: 10.1103/physrevc.88.015808
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Mean proton andα-particle reduced widths of the Porter-Thomas distribution and astrophysical applications

Abstract: The Porter-Thomas distribution is a key prediction of the Gaussian orthogonal ensemble in random matrix theory. It is routinely used to provide a measure for the number of levels that are missing in a given resonance analysis. The Porter-Thomas distribution is also of crucial importance for estimates of thermonuclear reaction rates where the contributions of certain unobserved resonances to the total reaction rate need to be taken into account. In order to estimate such contributions by randomly sampling over … Show more

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Cited by 27 publications
(75 citation statements)
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“…c A first step in this regard was the recent extraction of mean reduced widths from high-resolution data measured at TUNL for target nuclei in the A = 28−40 (α-particles) and A = 34−67 (protons) mass ranges. 54 For example, a mean value of θ 2 α = 0.018, averaged over target nuclei, spin-parities, and excitation energies, was obtained for α-particles, almost a factor of two larger than the preliminary value suggested in Longland et al 48 An example for the relevance of these results is given in Fig. 10.…”
Section: B Upper Limits Of Nuclear Physics Input Parametersmentioning
confidence: 86%
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“…c A first step in this regard was the recent extraction of mean reduced widths from high-resolution data measured at TUNL for target nuclei in the A = 28−40 (α-particles) and A = 34−67 (protons) mass ranges. 54 For example, a mean value of θ 2 α = 0.018, averaged over target nuclei, spin-parities, and excitation energies, was obtained for α-particles, almost a factor of two larger than the preliminary value suggested in Longland et al 48 An example for the relevance of these results is given in Fig. 10.…”
Section: B Upper Limits Of Nuclear Physics Input Parametersmentioning
confidence: 86%
“…However, the experimental values cover only a small part of the A-J π -E x parameter space and it is clearly desirable to have access to θ 2 values for all cases of interest. Considering that the data analyzed in Pogrebnyak et al 54 were accumulated over a period of more than 40 years at the now decommissioned 3-MeV Van de Graaff accelerator laboratory at TUNL, it is clear that the desired θ 2 values need to be obtained from nuclear theory, perhaps using the shell model. More work is needed in this regard for the future.…”
Section: B Upper Limits Of Nuclear Physics Input Parametersmentioning
confidence: 99%
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“…In this work, we randomly sample θ 2 α for all states in Category D from a Porter-Thomas distribution with a mean reduced width of θ 2 α = 0.03 ± 0.01. We obtain this value by extrapolating the recent results of Pogrebnyak et al [26] for nuclei with slightly larger mass numbers A. In the latter work, θ 2 α = 0.018 was found with a trend to increasing values for smaller mass numbers.…”
mentioning
confidence: 80%
“…Our recommended resonance strengths, ωγ αp , are listed in Table I. For states in category D we provide ωγ in parenthesis which are calculated from Γ α = 0.03×Γwhere the factor of 0.03 is taken from the systematics of reduced widths [26]. Note that these resonance strengths are used in the presentation of the recommended astrophysical S-factor in the next paragraph; however, these numbers do not enter directly in the calculation of N A σv because here a Porter-Thomas distribution will be sampled using the Monte-Carlo method.…”
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confidence: 99%