Presolar stardust grains found in primitive meteorites are believed to retain the isotopic composition of stellar outflows at the time of grain condensation. Therefore, laboratory measurements of their isotopic ratios represent sensitive probes for investigating open questions related to stellar evolution, stellar explosions, nucleosynthesis, mixing mechanisms, dust formation, and galactic chemical evolution. For a few selected presolar grains, classical novae have been discussed as a potential source. For SiC, silicate, and graphite presolar grains, the association is based on the observation of small N ( 12 C)/ N ( 13 C) and N ( 14 N)/ N ( 15 N) number abundance ratios compared to solar values, and abundance excesses in 30 Si relative to 29 Si, as previously predicted by models of classical novae. We report on a direct measurement of the 29 Si(p, γ ) 30 P reaction, which strongly impacts simulated δ 29 Si values from classical novae. Our new experimental 29 Si(p, γ ) 30 P thermonuclear reaction rate differs from previous results by up to 50% in the classical nova temperature range ( T = 100–400 MK), while the rate uncertainty is reduced by up to a factor of 3. Using our new reaction rate in Monte Carlo reaction network and hydrodynamic simulations of classical novae, we estimate δ 29 Si values with much reduced uncertainties. Our results establish δ 29 Si values measured in presolar grains as a sensitive probe for assessing their classical nova paternity. We also demonstrate that δ 30 Si values from nova simulations are currently not a useful diagnostic tool unless the large uncertainty of the 30 P(p, γ ) 31 S reaction rate can be significantly reduced.
Downen, Lori, et al. "Hydrogen Burning of <sup>29</sup> Si and Its Impact on Presolar Stardust Grains from Classical Novae." The Astrophysical Journal, vol. 928, no. 2, Apr. 2022. https://doi.org/10.3847/1538-4357/ac582b
Downen, Lori, Iliadis, Christian, Champagne, Art, Clegg, Thomas, Coc, Alain, & José, Jordi (2022). Hydrogen Burning of <sup>29</sup> Si and Its Impact on Presolar Stardust Grains from Classical Novae. The Astrophysical Journal, 928(2). https://doi.org/10.3847/1538-4357/ac582b
Downen, Lori, Iliadis, Christian, Champagne, Art, et al., "Hydrogen Burning of <sup>29</sup> Si and Its Impact on Presolar Stardust Grains from Classical Novae," The Astrophysical Journal 928, no. 2 (2022), https://doi.org/10.3847/1538-4357/ac582b
@article{osti_1860992,
author = {Downen, Lori and Iliadis, Christian and Champagne, Art and Clegg, Thomas and Coc, Alain and José, Jordi},
title = {Hydrogen Burning of <sup>29</sup> Si and Its Impact on Presolar Stardust Grains from Classical Novae},
annote = {Abstract Presolar stardust grains found in primitive meteorites are believed to retain the isotopic composition of stellar outflows at the time of grain condensation. Therefore, laboratory measurements of their isotopic ratios represent sensitive probes for investigating open questions related to stellar evolution, stellar explosions, nucleosynthesis, mixing mechanisms, dust formation, and galactic chemical evolution. For a few selected presolar grains, classical novae have been discussed as a potential source. For SiC, silicate, and graphite presolar grains, the association is based on the observation of small N ( 12 C)/ N ( 13 C) and N ( 14 N)/ N ( 15 N) number abundance ratios compared to solar values, and abundance excesses in 30 Si relative to 29 Si, as previously predicted by models of classical novae. We report on a direct measurement of the 29 Si(p, γ ) 30 P reaction, which strongly impacts simulated δ 29 Si values from classical novae. Our new experimental 29 Si(p, γ ) 30 P thermonuclear reaction rate differs from previous results by up to 50% in the classical nova temperature range ( T = 100–400 MK), while the rate uncertainty is reduced by up to a factor of 3. Using our new reaction rate in Monte Carlo reaction network and hydrodynamic simulations of classical novae, we estimate δ 29 Si values with much reduced uncertainties. Our results establish δ 29 Si values measured in presolar grains as a sensitive probe for assessing their classical nova paternity. We also demonstrate that δ 30 Si values from nova simulations are currently not a useful diagnostic tool unless the large uncertainty of the 30 P(p, γ ) 31 S reaction rate can be significantly reduced. },
doi = {10.3847/1538-4357/ac582b},
url = {https://www.osti.gov/biblio/1860992},
journal = {The Astrophysical Journal},
issn = {ISSN 0004-637X},
number = {2},
volume = {928},
place = {United States},
publisher = {American Astronomical Society},
year = {2022},
month = {04}}
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