Cool Bottom Processes on the Thermally Pulsing Asymptotic Giant Branch and the Isotopic Composition of Circumstellar Dust Grains

Abstract

We examine the effects of cool bottom processing (CBP) on the isotopic ratios ^(18)O/^(16)O, ^(17)O/^(16)O, ^(14)N/^(15)N, ^(26)Al/^(27)Al, C/O, and N/O in the convective envelope during the thermally pulsing asymptotic giant branch (TP-AGB) phase of evolution in a 1.5 M_☉ initial mass star of solar initial composition. We use a parametric model that treats extra mixing by introducing mass flow between the convective envelope and the underlying radiative zone. The parameters of this model are the mass circulation rate (Ṁ) and the maximum temperature (TP) experienced by the circulating material. The effects of nuclear reactions in the flowing matter were calculated using a set of static structures of the radiative zone selected from particular times in a complete stellar evolution calculation. The compositions of the flowing material were obtained, and the resulting changes in the envelope determined. No major shifts in the star's energy budget occur from the imposed CBP if log TP 7.6. Abundant ^(26)Al was produced by CBP for log TP > 7.65. While ^(26)Al/^(27)Al depends on TP, the other isotopic ratios depend dominantly on the circulation rate. The relationship is shown between models of CBP as parameterized by a diffusion formalism within the stellar evolution model and those using the mass-flow formalism employed here. They are shown to be effectively equivalent. In general, the CBP treatment readily permits calculation of envelope compositions as affected by different degrees of extra mixing, based on stellar structures computed by normal stellar evolution models. Using these results, the isotopic ratios under conditions of C/O 1 are compared with the data on circumstellar dust grains. It is found that the ^(18)O/^(16)O, ^(17)O/^(16)O, and ^(26)Al/^(27)Al observed for oxide grains formed at C/O 1) require that many of their stellar sources must have had ^(14)N/^(15)N at least a factor of 4 lower than the solar value. This allows a self-consistent description of all these isotopes in most SiC grains. The rare grains with ^(12)C/^(13)C < 10 cannot be produced by any red giant or AGB source, nor are they reconcilable with novae sources.