Metals versus Non-metals: Chemical Evolution of Hydrogen and Helium Isotopes in the Milky Way
Abstract
Star formation drives changes in the compositions of galaxies, fusing H and He into heavier nuclei. This paper investigates the differences in abundance evolution between metal and non-metal isotopes using recent models of Galactic chemical evolution appropriate for the thin disk epoch. A strong degeneracy arises between metal yields from stellar populations and the mean Galactocentric radial velocity of the interstellar medium (ISM). Similar metallicities arise when increases (decreases) in metal yields are combined with increases (decreases) to the gas flow velocity. A similar degeneracy exists between metal yields and the rate of gas ejection from the ISM. We demonstrate that this degeneracy can be confidently broken with precise measurements of the hydrogen (D/H) and helium (3He/4He) isotope ratios in the Galactic ISM. At fixed O/H, higher metal yields lead to higher D/H and lower 3He/4He. Measurements available to date are not sufficiently precise or numerous to draw confident conclusions. A detailed inventory of non-metal isotopes in the Milky Way would provide critical empirical constraints for stellar and galactic astrophysics, as well as a new test of Big Bang Nucleosynthesis. We forecast that only 4 additional measurements of 3He/4He within 3 kpc of the Sun are required to measure the primordial 3He/4He ratio at 30\% precision. In parallel, empirical benchmarks on metal yields also have the power to inform stellar models, since absolute yield calculations carry factor of 2-3 uncertainties related to various complex processes (e.g., rotational mixing, convection, mass loss, failed supernovae).
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