Survival of Nature's Rarest Isotope 180Ta under Stellar Conditions

The nucleosynthesis of nature's rarest isotope 180Ta depends sensitively on the temperature of the astrophysical environment because of depopulation of the long-living isomeric state via intermediate states to the short-living ground state by thermal photons. Reaction rates for this transition have been measured in the laboratory. These ground state rates understimate the stellar rates dramatically because under stellar conditions intermediate states are mainly populated by excitations from thermally excited states in 180mTa. Full thermalization of 180Ta is already achieved for typical s-process temperatures around kT = 25 keV. Consequently, for the survival of 180Ta in the s-process fast convective mixing is required which has to transport freshly synthesized 180Ta to cooler regions. In supernova explosions 180Ta is synthesized by photon- or neutrino-induced reactions at temperatures above T9 = 1 in thermal equilibrium; independent of the production mechanism, freeze-out from thermal equilibrium occurs at kT approx 40 keV, and only 35 +- 4 % of the synthesized 180Ta survive in the isomeric state.