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Autori principali: Heiger, Mairéad E., Ji, Alexander P., Speagle, Joshua S., Li, Ting S., Savino, Alessandro, Sandford, Nathan R., Kirby, Evan N., Reyes, Mithi A. C. de los, Simon, Joshua D.
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2602.22333
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author Heiger, Mairéad E.
Ji, Alexander P.
Speagle, Joshua S.
Li, Ting S.
Savino, Alessandro
Sandford, Nathan R.
Kirby, Evan N.
Reyes, Mithi A. C. de los
Simon, Joshua D.
author_facet Heiger, Mairéad E.
Ji, Alexander P.
Speagle, Joshua S.
Li, Ting S.
Savino, Alessandro
Sandford, Nathan R.
Kirby, Evan N.
Reyes, Mithi A. C. de los
Simon, Joshua D.
contents The chemical abundances of a stellar population encode information about nucleosynthesis and its astrophysical sites, but this information is confounded by the specific star formation history of the host galaxy. As a result, placing empirical constraints on supernova yields and timing using abundances has been very challenging. We introduce a galactic chemical evolution model DLEIY that uses an observed star formation history and metallicity distribution to reduce these confounding factors. Using a joint statistical model of the dwarf spheroidal galaxies Sculptor and Fornax, simultaneous constraints on population-averaged yields and galactic outflows are achieved with DLEIY, without fixing the absolute scale of nucleosynthetic yields. The Fe yield from core collapse supernovae is consistent with existing theoretical yield models, while the measured Mg yield is a factor of 2-4 higher, corroborating previous suggestions that yield models may under-predict [Mg/Fe]. We also find that the rate of Type Ia supernovae is enhanced by about a factor of 5 relative to field galaxies, and the delay-time distribution goes as $\sim t^{-2}$, a much steeper relationship than that measured from supernova surveys ($\sim t^{-1.1}$). These findings may suggest a metallicity dependence of the Type Ia rate and delay-time distribution.
format Preprint
id arxiv_https___arxiv_org_abs_2602_22333
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle It's a matter of time: Empirical Constraints on Supernova Yields and Delay Times from Dwarf Spheroidal Galaxies
Heiger, Mairéad E.
Ji, Alexander P.
Speagle, Joshua S.
Li, Ting S.
Savino, Alessandro
Sandford, Nathan R.
Kirby, Evan N.
Reyes, Mithi A. C. de los
Simon, Joshua D.
Astrophysics of Galaxies
The chemical abundances of a stellar population encode information about nucleosynthesis and its astrophysical sites, but this information is confounded by the specific star formation history of the host galaxy. As a result, placing empirical constraints on supernova yields and timing using abundances has been very challenging. We introduce a galactic chemical evolution model DLEIY that uses an observed star formation history and metallicity distribution to reduce these confounding factors. Using a joint statistical model of the dwarf spheroidal galaxies Sculptor and Fornax, simultaneous constraints on population-averaged yields and galactic outflows are achieved with DLEIY, without fixing the absolute scale of nucleosynthetic yields. The Fe yield from core collapse supernovae is consistent with existing theoretical yield models, while the measured Mg yield is a factor of 2-4 higher, corroborating previous suggestions that yield models may under-predict [Mg/Fe]. We also find that the rate of Type Ia supernovae is enhanced by about a factor of 5 relative to field galaxies, and the delay-time distribution goes as $\sim t^{-2}$, a much steeper relationship than that measured from supernova surveys ($\sim t^{-1.1}$). These findings may suggest a metallicity dependence of the Type Ia rate and delay-time distribution.
title It's a matter of time: Empirical Constraints on Supernova Yields and Delay Times from Dwarf Spheroidal Galaxies
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2602.22333