par Neyskens, Pieter 
;Van Eck, Sophie ;Jorissen, Alain ;Goriely, Stéphane ;Siess, Lionel ;Plez, Bertrand
Référence Nature (London), 517, 7533, page (174-176), 14050
Publication Publié, 2015-01-08
;Van Eck, Sophie ;Jorissen, Alain ;Goriely, Stéphane ;Siess, Lionel ;Plez, BertrandRéférence Nature (London), 517, 7533, page (174-176), 14050
Publication Publié, 2015-01-08
Article révisé par les pairs
| Résumé : | Roughly half of the heavy elements (atomic mass greater than that of iron) are believed to be synthesized in the late evolutionary stages of stars with masses between 0.8 and 8 solar masses. Deep inside the star, nuclei (mainly iron) capture neutrons and progressively build up (through the slow-neutron-capture process, or s-process) heavier elements that are subsequently brought to the stellar surface by convection. Two neutron sources, activated at distinct temperatures, have been proposed: 13C and 22Ne, each releasing one neutron per α-particle (4He) captured. To explain the measured stellar abundances, stellar evolution models invoking the 13C neutron source (which operates at temperatures of about one hundred million kelvin) are favoured. Isotopic ratios in primitive meteorites, however, reflecting nucleosynthesis in the previous generations of stars that contributed material to the Solar System, point to higher temperatures (more than three hundred million kelvin), requiring at least a late activation of 22Ne. Here we report a determination of the s-process temperature directly in evolved low-mass giant stars, using zirconium and niobium abundances, independently of stellar evolution models. The derived temperature supports 13C as the s-process neutron source. The radioactive pair 93Zr–93Nb used to estimate the s-process temperature also provides, together with the pair 99Tc–99Ru, chronometric information on the time elapsed since the start of the s-process, which we determine to be one million to three million years. |
