The heaviest chemical elements are naturally produced by the rapid neutron-capture process (
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r -process) during neutron star mergers or supernovae. Ther -process production of elements heavier than uranium (transuranic nuclei) is poorly understood and inaccessible to experiments so must be extrapolated by using nucleosynthesis models. We examined element abundances in a sample of stars that are enhanced inr -process elements. The abundances of elements ruthenium, rhodium, palladium, and silver (atomic numbersZ = 44 to 47; mass numbersA = 99 to 110) correlate with those of heavier elements (63 ≤Z ≤ 78,A > 150). There is no correlation for neighboring elements (34 ≤Z ≤ 42 and 48 ≤Z ≤ 62). We interpret this as evidence that fission fragments of transuranic nuclei contribute to the abundances. Our results indicate that neutron-rich nuclei with mass numbers >260 are produced inr -process events. -
Abstract We present new observational benchmarks of rapid neutron-capture process (
r -process) nucleosynthesis for elements at and between the first (A ∼ 80) and second (A ∼ 130) peaks. Our analysis is based on archival ultraviolet and optical spectroscopy of eight metal-poor stars with Se (Z = 34) or Te (Z = 52) detections, whoser -process enhancement varies by more than a factor of 30 (−0.22 ≤ [Eu/Fe] ≤ +1.32). We calculate ratios among the abundances of Se, Sr through Mo (38 ≤Z ≤ 42), and Te. These benchmarks may offer a new empirical alternative to the predicted solar systemr -process residual pattern. The Te abundances in these stars correlate more closely with the lighterr -process elements than the heavier ones, contradicting and superseding previous findings. The small star-to-star dispersion among the abundances of Se, Sr, Y, Zr, Nb, Mo, and Te (≤0.13 dex, or 26%) matches that observed among the abundances of the lanthanides and thirdr -process-peak elements. The concept ofr -process universality that is recognized among the lanthanide and third-peak elements inr -process-enhanced stars may also apply to Se, Sr, Y, Zr, Nb, Mo, and Te, provided the overall abundances of the lighterr -process elements are scaled independently of the heavier ones. The abundance behavior of the elements Ru through Sn (44 ≤Z ≤ 50) requires further study. Our results suggest that at least one relatively common source in the early Universe produced a consistent abundance pattern among some elements spanning the first and secondr -process peaks.