CNO hydrogen burning studied deep underground

Bemmerer, D.; Confortola, F.; Lemut, A.; Bonetti, R.; Broggini, C.; Corvisiero, P.; Costantini, H.; Cruz, J.; Formicola, A.; Fülöp, Zs.; Gervino, G.; Guglielmetti, A.; Gustavino, C.; Gyürky, Gy.; Imbriani, G.; Jesus, A.P.; Junker, M.; Limata, B.; Menegazzo, R.; Prati, P.; Roca, V.; Rogalla, Detlef; Rolfs, C.; Alvarez, C. Rossi; Schümann, F.; Somorjai, E.; Straniero, O.; Strieder, F.; Terrasi, F.; Trautvetter, H. P.

doi:10.1007/3-540-32843-2_24

Cited by 2 publications

(3 citation statements)

References 45 publications

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“…[2001] for a detailed discussion). For the 14 N + p → 15 O + γ reaction, the Doherty models use the rate from NACRE, while the Karakas models use the rate from Bemmerer et al. (2006), which is approximately 30% smaller.…”

Section: Super‐agb Stellar Modelsmentioning

confidence: 99%

“…It mainly affects the final central C ⁄ O ratio and possibly the explosive nucleosynthesis of some intermediate-mass elements forged in the C-burning shell (see Imbriani et al [2001] for a detailed discussion). For the 14 N + p fi 15 O + c reaction, the Doherty models use the rate from NACRE, while the Karakas models use the rate from Bemmerer et al (2006), which is approximately 30% smaller. This rate is the bottleneck of the CNO cycle and has an impact on its energy generation strongly affecting stellar evolution (Imbriani et al 2004) and nucleosynthesis (Palmerini et al 2011).…”

Section: Super-agb Stellar Modelsmentioning

confidence: 99%

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Short‐lived radioactivity in the early solar system: The Super‐AGB star hypothesis

Lugaro

Doherty

Karakas

et al. 2012

Meteorit & Planetary Scien

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Abstract-The composition of the most primitive solar system condensates, such as calciumaluminum-rich inclusions (CAIs) and micron-sized corundum grains, show that short-lived radionuclides (SLR), e.g., 26 Al, were present in the early solar system. Their abundances require a local or stellar origin, which, however, is far from being understood. We present for the first time the abundances of several SLR up to 60 Fe predicted from stars with initial mass in the range approximately 7-11 M x . These stars evolve through core H, He, and C burning. After core C burning they go through a ''Super''-asymptotic giant branch (Super-AGB) phase, with the H and He shells activated alternately, episodic thermal pulses in the He shell, a very hot temperature at the base of the convective envelope (approximately 10 8 K), and strong stellar winds driving the H-rich envelope into the surrounding interstellar medium. The final remnants of the evolution of Super-AGB stars are mostly O-Ne white dwarfs. Our Super-AGB models produce 26 Al ⁄ 27 Al yield ratios approximately 0.02-0.26. These models can account for the canonical value of the 26 Al ⁄ 27Al ratio using dilutions with the solar nebula of the order of 1 part of Super-AGB mass per several 10 2 to several 10 3 of solar nebula mass, resulting in associated changes in the O-isotope composition in the range D 17 O from 3 to 20&. This is in agreement with observations of the O isotopic ratios in primitive solar system condensates, which do not carry the signature of a stellar polluter. The radionuclides 41 Ca and 60 Fe are produced by neutron captures in Super-AGB stars and their meteoritic abundances are also matched by some of our models, depending on the nuclear and stellar physics uncertainties as well as the meteoritic experimental data. We also expect and are currently investigating Super-AGB production of SLR heavier than iron, such as 107 Pd.

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Section: Super‐agb Stellar Modelsmentioning

confidence: 99%

Section: Super-agb Stellar Modelsmentioning

confidence: 99%

Short‐lived radioactivity in the early solar system: The Super‐AGB star hypothesis

Lugaro

Doherty

Karakas

et al. 2012

Meteorit & Planetary Scien

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“…Resonant capture reactions on stable and long-lived radioactive targets have been inves-tigated with intense proton and α beams [293,294]. The most recent examples for direct measurements of radiative capture reactions are 23 Na(p, γ) 24 Mg and 17 O(p, γ) 18 F studied at the Laboratory for Experimental Nuclear Astrophysics (LENA) at TUNL [295][296][297] and the 3 He(α,γ) 7 Be [298-300] and 14 N(p, γ) 15 O reactions [301][302][303][304] at the Laboratory Underground Nuclear Astrophysics (LUNA) facility [305,306] located in the Gran Sasso Laboratory.…”

Section: Targetsmentioning

confidence: 99%

Nuclear Astrophysics with Radioactive Beams

Bertulani,

Gade

2009

Preprint

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The quest to comprehend how nuclear processes influence astrophysical phenomena is driving experimental and theoretical research programs worldwide. One of the main goals in nuclear astrophysics is to understand how energy is generated in stars, how elements are synthesized in stellar events and what the nature of neutron stars is. New experimental capabilities, the availability of radioactive beams and increased computational power paired with new astronomical observations have advanced the present knowledge. This review summarizes the progress in the field of nuclear astrophysics with a focus on the role of indirect methods and reactions involving beams of rare isotopes.

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CNO hydrogen burning studied deep underground

Cited by 2 publications

References 45 publications

Short‐lived radioactivity in the early solar system: The Super‐AGB star hypothesis

Short‐lived radioactivity in the early solar system: The Super‐AGB star hypothesis

Nuclear Astrophysics with Radioactive Beams

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