Calculation Of The 12C+a Capture Cross Section at Stellar Energies

Barker, F.C.

doi:10.1071/ph710777

Cited by 74 publications

(27 citation statements)

References 6 publications

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“…Barker [4,5] proposed the use of the β-delayed α-particle emission spectrum of 16 N to constrain S E1 , the p-wave component of the astrophysical cross section factor. At the time of these calculations [4,5], a single β-delayed α-particle emission spectrum with very high statistics ( > 36 million counts) existed. These data were measured at Mainz [8,9,10] in a successful measurement of the parity violating 1.281 MeV α-particle decay.…”

Section: Introductionmentioning

confidence: 99%

“…α-particles emitted from the continuum of 16 O populated by the β-decay of 16 N) has been predicted to provide a constraint on the cross section of this reaction [4,5,6,7], but it requires a measurement of a β-decay of 16 N with a sensitivity for a Branching Ratio (BR) of the order of 10 −9 . In particular, the low energy portion of the alpha-particle spectrum has been predicted to be sensitive to the reduced α-particle width of the bound 1 − state in 16 O; however, it cannot directly determine the mixing phase in the 12 C(α, γ) 16 O reaction of the two interfering states at 7.12 MeV and 9.58 MeV in 16 O.…”

Section: Introductionmentioning

confidence: 99%

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Further measurement of the beta-delayed alpha-particle emission of 16N

et al. 1997

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Further measurement of the beta-delayed alpha-particle emission of 16N

et al. 1997

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“…In 1971, Barker [7] proposed an experimental method to investigate the C+α. Information about the E 1 component of the astrophysical factor can be extracted from the height of the peak located at roughly E c.m.…”

Section: State Of the Artmentioning

confidence: 99%

“…Di Pietro 2) , P. Figuera 2) , M. Gulino 2,3) , M. La Cognata 2) , M. Lattuada 1,2) , C. Spitaleri 1,2) , H. Yamaguchi , S. Kubono 5) , Y. Wakabayashi 5) , T. Hashimoto 6) , N. Iwasa 7) , Y. Okoda 7) , K. Ushio 7) , T. Teranishi 8) , M. Mazzocco 9) , C. Signorini 9) , D. Torresi O. Carbon and oxygen abundance depends on the relative cross section of the reaction and on stellar temperature and density.…”

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β-delayed α decay of 16N and the 12C(α,γ)16O cross section at astrophysical energies: A new experimental approach

Sanfilippo

Cherubini

Hayakawa

et al. 2015

AIP Conference Proceedings

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Abstract.The 12 C(α,γ) 16 O reaction at energies corresponding to the quiescent helium burning in massive stars is regarded as one of the most important processes in nuclear astrophysics. Although this process has being studied for over four decades, our knowledge of its cross section at the energies of interest for astrophysics is still widely unsatisfactory. Indeed, no experimental data are available around 300 keV and in the energy region of astrophysical interest extrapolations are performed using some theoretical approaches, usually R-matrix calculations. Consequently, the published astrophysical factors range from 1 to 288 keVb for SE1(300) and 7 to 120 keVb for SE2(300), especially because of the unknown contribution coming from subthreshold resonances. To improve the reliability of these extrapolations, data from complementary experiments, such as elastic and quasi-elastic α scattering on 12 C, α-transfer reactions to 16 O, and 16 N decay are usually included in the analysis. Here the β-delayed α decay of 16 N is used to infer information on the 12 C(α,γ)16 O reaction and a new experimental technique is suggested.

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“…We emphasize that these predictions were published approximately five years prior to the observation of the anomaly interference structure around 1.1 MeV [13,9]. The previously measured beta-delayed alpha-particle emission of 16 N [19] was analyzed using R-matrix theory by Barker [20] and lately by Ji, Filippone, Humblet and Koonin [21]. They conclude that the data measured at higher energies is dominated by the quasi bound 1 − state in 16 O at 9.63 MeV and shows little sensitivity to the interference with the bound 1 − state.…”

Section: Nucleosynthesis In Massive Starsmentioning

confidence: 99%

Nuclear astrophysics with secondary (Radioactive) beams

Gai

1993

Progress in Particle and Nuclear Physics

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Some problems in nuclear astrophysics are discussed with emphasize on the ones central to the field which were not solved over the last two decades, including Helium Burning in massive stars (the 12 C(α, γ) 16 O reaction) and the 8 B Solar Neutrino Flux Problem (the 7 Be(p, γ) 8 B reaction). We demonstrate that a great deal of progress was achieved by measuring the time reverse process(es): the beta-delayed alpha-particle emission of 16 N and the Coulomb dissociation of 8 B, using Radioactive Beams (of 16 N and 8 B). In this way an amplification of the sought for cross section was achieved, allowing a measurement of the small cross section(s) of relevance for stellar (solar) processes. RESUMEN.Se discuten algunos problemas de astrofísica nuclear conénfasis en aquellos que son centrales de este campo que no han sido resueltos en lasúltimas dos décadas, incluyendose el consumo de Helio en las estrellas masivas (la reacción 12 C(α, γ) 16 O ) y el problema del flujo de Neutrinos Solares de 8 B (la reaccion 7 Be(p, γ) 8 B). Demostramos que se han hecho grandes progresos mediante la medida de los procesos invertidos en el tiempo: la emisión de partícula alfa retardada por beta de 16 N y la disociación coulombiana de 8 B, usando Haces Radioactivos (de 16 N y 8 B). En esta forma se logro una ampliación de la búsqueda de la sección, permitiendo la medida de seccion(es) pequeña(s) de relevancia para procesos estelares (solares).

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Calculation Of The 12C+a Capture Cross Section at Stellar Energies

Cited by 74 publications

References 6 publications

Further measurement of the beta-delayed alpha-particle emission of 16N

Further measurement of the beta-delayed alpha-particle emission of 16N

β-delayed α decay of 16N and the 12C(α,γ)16O cross section at astrophysical energies: A new experimental approach

Nuclear astrophysics with secondary (Radioactive) beams

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