The effect of 12C + 12C rate uncertainties on the weak s-process component

Fryer, Christopher Lee; Hungerford, Aimee L; Hirschi, Raphael; Pignatari, Marco; Bennett, Michael E; Diehl, Steven; Herwig, Falk; Hillary, William; Richman, Debra; Rockefeller, Gabriel; Timmes, Frank X; Wiescher, Michael

Title: The effect of 12C + 12C rate uncertainties on the weak s-process component

Conference · Fri Sep 10 00:00:00 EDT 2010

OSTI ID:1033571

Fryer, Christopher Lee ^[1]; Hungerford, Aimee L ^[1]; Hirschi, Raphael ^[2]; Pignatari, Marco ^[3]; Bennett, Michael E ^[2]; Diehl, Steven ^[1]; Herwig, Falk ^[4]; Hillary, William ^[4]; Richman, Debra ^[4]; Rockefeller, Gabriel ^[1]; Timmes, Frank X ^[5]; Wiescher, Michael ^[6]

Los Alamos National Laboratory
KEELE UNIV.
TRIUMF
CANADA
UNIV OF ARIZONA
UNIV OF NOTRE DAME

The contribution by massive stars (M > 15M{sub {circle_dot}}) to the weak s-process component of the solar system abundances is primarily due to the {sup 22}Ne neutron source, which is activated near the end of helium-core burning. The residual {sup 22}Ne left over from helium-core burning is then reignited during carbon burning, initiating further s-processing that modifies the isotopic distribution. This modification is sensitive to the stellar structure and the carbon burning reaction rate. Recent work on the {sup 12}C + {sup 12}C reaction suggests that resonances located within the Gamow peak may exist, causing a strong increase in the astrophysical S-factor and consequently the reaction rate. To investigate the effect of such a rate, 25M{sub {circle_dot}} stellar models with different carbon burning rates, at solar metallicity, were generated using the Geneva Stellar Evolution Code (GENEC) with nucleosynthesis post-processing calculated using the NuGrid Multi-zone Post-Processing Network code (MPPNP). A strongly enhanced rate can cause carbon burning to occur in a convective core rather than a radiative one and the convective core mixes the matter synthesized there up into the carbon shell, significantly altering the initial composition of the carbon-shell. In addition, an enhanced rate causes carbon-shell burning episodes to ignite earlier in the evolution of the star, igniting the {sup 22}Ne source at lower temperatures and reducing the neutron density.

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Research Organization:: Los Alamos National Laboratory (LANL), Los Alamos, NM (United States)

Sponsoring Organization:: USDOE

DOE Contract Number:: AC52-06NA25396

OSTI ID:: 1033571

Report Number(s):: LA-UR-10-06146; LA-UR-10-6146; TRN: US201203%%4

Resource Relation:: Conference: 11th symposium on nuclei in the cosmos ; July 19, 2010 ; Heidelberg Germany

Country of Publication:: United States

Language:: English

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Related Subjects

71 CLASSICAL AND QUANTUM MECHANICS
GENERAL PHYSICS
79 ASTROPHYSICS
COSMOLOGY AND ASTRONOMY
CARBON
CARBON BURNING
DISTRIBUTION
MODIFICATIONS
NEON 22
NEUTRON DENSITY
NEUTRON SOURCES
NUCLEI
NUCLEOSYNTHESIS
REACTION KINETICS
S PROCESS
SOLAR SYSTEM
STARS
UNIVERSE

Title: The effect of 12C + 12C rate uncertainties on the weak s-process component

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