STARLIB: A next-generation reaction-rate library for nuclear astrophysics

Sallaska, A. L.; Iliadis, Christian; Chapmagne, A. E.; Timmes, F. X.; Starrfield, S.; Goriely, Stéphane

doi:10.22323/1.146.0230

Cited by 6 publications

(11 citation statements)

References 66 publications

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“…They are NOVA (38; 39; 40, and references therein) and MESA (41; 42; 43; 44; 45, and references therein). NOVA is a one-dimensional (1-D), implicit, hydrodynamic, computer code which includes a nuclear reaction network that has been extended to 187 nuclei (up to 64 Ge and including the pep reaction), the OPAL opacities (46, and references therein), the Starlib nuclear reaction rates (47), the Timmes equations of state (48; 49), and the nuclear reaction network solver developed by (50). NOVA also includes the (51) algorithm for mixing-length convection and the Potekhin electron conduction opacities described in (52, and references therein).…”

Section: The Stellar Evolution Codes: Nova and Mesamentioning

confidence: 99%

Hydrodynamic simulations of classical novae outbursts and their evolution to supernova Ia explosions

Starrfield¹,

Bose²,

Iliadis³

et al. 2021

Proceedings of the Golden Age of Cataclysmic Variables and Related Objects v — PoS(GOLDEN2019)

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Section: The Stellar Evolution Codes: Nova and Mesamentioning

confidence: 99%

Hydrodynamic simulations of classical novae outbursts and their evolution to supernova Ia explosions

Starrfield¹,

Bose²,

Iliadis³

et al. 2021

Proceedings of the Golden Age of Cataclysmic Variables and Related Objects v — PoS(GOLDEN2019)

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“…NOVA is a one-dimensional (1-D), implicit, hydrodynamic, computer code which has been well tested against a number of standard problems and weapon codes (45; 46). It includes a nuclear reaction network that has been extended to 187 nuclei (up to 64 Ge and including the pep reaction), the OPAL opacities (54, and references therein), the Starlib nuclear reaction rates (55), the Timmes equations of state (56; 57), and the nuclear reaction network solver developed by (58). NOVA also includes the (59) algorithm for mixing-length convection and the Potekhin electron conductivities described in (60, and references therein).…”

Section: The Stellar Evolution Codes: Nova and Mesamentioning

confidence: 99%

“…There are now a number of studies of grain formation in CN outbursts (78; 79; 80; 81; 82). In addition, we now use the STARLIB reaction rate library (55) which improves the rates for many of the light nuclear reactions. Temperature (K) Figure 4: The variation with time of the temperature in the deepest hydrogen-rich zone around the time when peak temperature occurs for the simulations with 25% core material and 75% accreted material.…”

Section: Accretion Onto Co Wds Where Mixing Of Core With Accreted Matmentioning

confidence: 99%

Hydrodynamic Simulations of Classical Novae: Accretion onto CO White Dwarfs as SN Ia Progenitors

Starrfield¹,

Bose²,

Iliadis³

et al. 2018

Proceedings of the Golden Age of Cataclysmic Variables and Related Objects IV — PoS(GOLDEN 2017)

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We report on our continuing studies of Classical Nova explosions by following the evolution of thermonuclear runaways (TNRs) on carbon-oxygen (CO) white dwarfs (WDs). We have varied both the mass of the WD and the composition of the accreted material. Rather than assuming that the material has mixed from the beginning, we now rely on the results of the multidimensional (multi-D) studies of mixing as a consequence of the TNRs in WDs that accreted only Solar matter. The multi-D studies find that mixing with the core occurs after the TNR is well underway and reach enrichment levels in agreement with observations of the ejecta abundances. We report on 3 studies in this paper. First, simulations in which we accrete only Solar matter with NOVA (our 1-D, fully implicit, hydro code). Second, we use MESA for similar studies in which we accrete only Solar material and compare the results. Third, we accrete Solar matter until the TNR is initiated and then switch the composition in the accreted layers to a mixed composition: either 25% core and 75% Solar or 50% core and 50% Solar. The amount of accreted material is inversely proportional to the initial 12 C abundance. Thus, accreting Solar material results in more material to fuel the outburst-much larger than in the earlier studies where mixed materials were used from the beginning. We tabulate the amount of ejected gases, their velocities, and abundances. We predict the amount of 7 Li and 7 Be produced and ejected by the explosion and compare our predictions to our Large Binocular Telescope (LBT) high dispersion spectra which determined the abundance of 7 Li in nova V5668 Sgr. Finally, many of these simulations eject significantly less mass than accreted and, therefore, the WD is growing in mass toward the Chandrasekhar Limit.

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“…20 Ne(p,γ) 21 Figure 1: TNRR of the different reactions involved in the NeNa cycle. 22 Na(p, γ) 23 Mg reaction rate is from [4]. 22 Ne(p, γ) 23 Na reaction rate is from [5].…”

Section: Introductionmentioning

confidence: 99%

“…The reaction rate has been calculated in 1999 by the NACRE collaboration [25] from the resonance measurements [8,9] and the direct capture component [9]. Later on, a similar evaluation has been performed in 2001 [14], updated in 2010 [10,11] and again in 2013 [4] by the STARLIB group, completely disregarding the uncertain resonances. As a result, the NACRE and the STARLIB compilations differ up to a factor of 1000.…”

Section: Introductionmentioning

confidence: 99%