Distinct First-to-Second Peak Yield Ratios and Timescales Reveal a Sub-dominant Prompt Channel

Abstract

Stellar abundances reveal non-monotonic [Y/Eu] and [Sr/Eu] evolution, a systematic decline with increasing [Eu/H] at low metallicity, a minimum at [Eu/H] -0.3 and then a rise at high metallicity. This behavior requires at least three distinct neutron-capture sources operating on different timescales. We develop a one-zone chemical-evolution model constraining their typical delay-times, rates, and yield ratios. Reproducing the observed [Y/Eu] and [Sr/Eu] sequences requires, a delayed r-process channel (most likely binary neutron-star mergers) dominating Eu production ( 95\% of total Eu). A prompt channel preferentially producing first-peak elements with minimal Eu, explaining the increasing [Y/Eu] at decreasing [Eu/H] below [Eu/H] -2.5; and delayed AGB s-process enrichment with delays greater than tmin = 0.3-0.6\,Gyr reproducing the late-time upturn in Y (Sr). Our model quantitatively reproduces all constraints, including the large [Y/Eu] ≈ 0.6 dex variation between the late-time rise [Eu/H] and the minimum value, the location of the minimum at [Eu/H] -0.3 and late-time rise. The first-to-second peak yield ratios correspond to [Y/Eu] ≈ -0.3 (prompt) and ≈ -0.8 (BNS mergers). The observed [Y/Eu] amplitude establishes a model-independent lower limit on the first to second peak yield ratio 3.4 between the prompt and delayed channels, ruling out models with similar prompt and delayed yield ratios. These results demonstrate that explaining the observed heavy-element abundance patterns requires multiple channels with distinct nucleosynthetic signatures and operational timescales, providing constraints on the relative rates, delay times, and yield patterns of candidate production sites.