The Importance of the <sup>13</sup>C(α,n)<sup>16</sup>O Reaction in Asymptotic Giant Branch Stars

Cristallo, S.; Cognata, M. La; Massimi, C.; Best, A.; Palmerini, S.; Straniero, O.; Trippella, O.; Busso, M.; Ciani, G. F.; Mingrone, F.; Piersanti, L.; Vescovi, D.

doi:10.3847/1538-4357/aac177

Cited by 61 publications

(65 citation statements)

References 73 publications

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“…This was the case of the astrophysically important 13 C(α,n) 16 O reaction [10] recently studied in direct kinematics at the Laboratory for Underground Nuclear Astrophysics (LUNA) [11,12] of the Laboratori Nazionali del Gran Sasso (LNGS), INFN, Italy. Because of the small cross-sections involved at the energies investigated (E α = 305 − 400 keV), intense α-particle beams were needed, leading to severe target degradation and frequent target replacements.…”

Section: Introductionmentioning

confidence: 99%

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

et al. 2020

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Direct measurements of reaction cross-sections at astrophysical energies often require the use of solid targets able to withstand high ion beam currents for extended periods of time. Thus, monitoring target thickness, isotopic composition, and target stoichiometry during data taking is critical to account for possible target modifications and to reduce uncertainties in the final cross-section results. A common technique used for these purposes is the Nuclear Resonant Reaction Analysis (NRRA), which however requires that a narrow resonance be available inside the dynamic range of the accelerator used. In cases when this is not possible, as for example the 13 C(α,n) 16 O reaction recently studied at low energies at the Laboratory for Underground Nuclear Astrophysics (LUNA) in Italy, alternative approaches must be found. Here, we present a new application of the shape analysis of primary γ rays emitted by the 13 C(p,γ) 14 N radiative capture reaction. This approach was used to monitor 13 C target degradation in situ during the 13 C(α,n) 16 O data taking campaign. The results obtained are in agreement with evaluations subsequently performed at Atomki (Hungary) using the NRRA method. A preliminary application for the extraction of the 13 C(α,n) 16 O reaction cross-section at one beam energy is also reported.

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Section: Introductionmentioning

confidence: 99%

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

et al. 2020

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“…A reservoir of 13 C, produced via the 12 C(p, c) 13 N(β + ]) 13 C reaction chain, forms the so-called 13 C pocket at the interface between the He-rich intershell and the H-rich envelope. As of today, the exact formation mechanism of such a pocket is still debated, as stated by Cristallo et al (2018). During this phase, which lasts some 10 4 years, the 13 C(α,n) 16 O reaction takes place and provides neutrons for the main s-process.…”

Section: Neutron Sources For the S-processmentioning

confidence: 99%

“…During this phase, which lasts some 10 4 years, the 13 C(α,n) 16 O reaction takes place and provides neutrons for the main s-process. In the article by Cristallo et al (2018), the authors claim that, in the most metal-rich stellar models with an almost solar composition, a small amount of 13 C might survive and be engulfed into the convective zone generated by the incoming thermal pulse. This scenario would affect several branching points along the s-process path, and excesses of 60 Fe, 86 Kr, 87 Rb, or 96 Zr are expected compared to the radiative (low neutron density) 13 C burst.…”

Section: Neutron Sources For the S-processmentioning

confidence: 99%

The Study of Key Reactions Shaping the Post-Main Sequence Evolution of Massive Stars in Underground Facilities

Ferraro

Ciani

Boeltzig

et al. 2021

Front. Astron. Space Sci.

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The chemical evolution of the Universe and several phases of stellar life are regulated by minute nuclear reactions. The key point for each of these reactions is the value of cross-sections at the energies at which they take place in stellar environments. Direct cross-section measurements are mainly hampered by the very low counting rate and by cosmic background; nevertheless, they have become possible by combining the best experimental techniques with the cosmic silence of an underground laboratory. In the nineties, the LUNA (Laboratory for Underground Nuclear Astrophysics) collaboration opened the era of underground nuclear astrophysics, installing first a homemade 50 kV and, later on, a second 400 kV accelerator under the Gran Sasso mountain in Italy: in 25 years of experimental activity, important reactions responsible for hydrogen burning could have been studied down to the relevant energies thanks to the high current proton and helium beams provided by the machines. The interest in the next and warmer stages of star evolution (i.e., post-main sequence and helium and carbon burning) drove a new project based on an ion accelerator in the MV range called LUNA-MV, able to deliver proton, helium, and carbon beams. The present contribution is aimed to discuss the state of the art for some selected key processes of post-main sequence stellar phases: 12C(α,γ)16O and 12C+12C are fundamental for helium and carbon burning phases, and 13C(α,n)16O and 22Ne(α,n)25Mg are relevant to the synthesis of heavy elements in AGB stars. The perspectives opened by an underground MV facility will be highlighted.

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“…Recently, two works [43,44] have determined new interesting spectroscopic information about the 6.356 MeV. The consequences on the 13 C(α, n) 16 O S-factor are presently under investigation [45,46].…”

Section: O Reactionmentioning

confidence: 99%

Resonant reactions of astrophysical interest studied by means of the Trojan Horse Method. Two case studies

et al. 2020

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Resonant reactions in astrophysics play and important role as unexpected resonances may enhance the astrophysical factor with respect to the direct reaction contribution, altering the predicted nucleosynthesis scenarios by changing, for instance, the expected nucleosynthesis path. They also are of great interest in nuclear structure studies, since the determination of energies, spinparities and partial widths sheds light on the occurrence of cluster structures, for instance. However, nuclear reactions in most astrophysical environments usually take place at energies below about 1 MeV, leading to an exponential decrease of the cross sections due to the effect of the penetration of the Coulomb barrier. Also, at energies so low to be comparable with those associated to electronic degrees of freedom, the effect of atomic and/or molecular clouds cannot be neglected, resulting in a shielding of nuclear charges and in an enhancement of the cross sections with respect to the case of bare nuclei (the so called electron screening effect). Owing to vanishingly small cross sections and ambiguities in the extrapolation due to the electron screening, supplying accurate cross sections for astrophysical modeling is extremely challenging. Indirect methods have been introduced to explore the energy range of astrophysical interest with no need of extrapolation, even guided by theoretical arguments. In particular, the Trojan Horse Method makes use of quasi-free reactions with three particles in the exit channel, a + A → c +C + s, to deduce the cross section of the reaction of astrophysical interest, a + x → c + C, under the hypothesis that A shows a strong x + s cluster structure. Even if measurements are carried out above astrophysical energies to be free from Coulomb suppression and electron screening, the range of astrophysical interest can be covered thanks to the x − s intercluster motion and binding energy. In these proceedings we will show the application of the THM, in the case of resonant reactions, using the generalised R-matrix approach introduced by A.M. Mukhamedzhanov. We will discuss the possibility to extract resonance parameters from the Trojan Horse data and perform a full spectroscopic study of low-energy and even sub-threshold resonances. In particular, we will focus on the 19 F(p, α) 16 O and the 13 C(α, n) 16 O reactions, of particular importance in the case of asymptotic giant branch stars and in the synthesis of heavy elements by means of the s-process. *

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The Importance of the ¹³C(α,n)¹⁶O Reaction in Asymptotic Giant Branch Stars

Cited by 61 publications

References 73 publications

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

The Study of Key Reactions Shaping the Post-Main Sequence Evolution of Massive Stars in Underground Facilities

Resonant reactions of astrophysical interest studied by means of the Trojan Horse Method. Two case studies

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The Importance of the 13C(α,n)16O Reaction in Asymptotic Giant Branch Stars

Cited by 61 publications

References 73 publications

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

A new approach to monitor $$^{13}\hbox {C}$$-targets degradation in situ for $$^{13}\hbox {C}(\alpha ,\hbox {n})^{16}\hbox {O}$$ cross-section measurements at LUNA

The Study of Key Reactions Shaping the Post-Main Sequence Evolution of Massive Stars in Underground Facilities

Resonant reactions of astrophysical interest studied by means of the Trojan Horse Method. Two case studies

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The Importance of the ¹³C(α,n)¹⁶O Reaction in Asymptotic Giant Branch Stars