Diffusion in hot subdwarf progenitors from the common envelope channel

• Published in: Open astronomy Vol. 26; no. 1; pp. 214 - 218
• Main Authors: Byrne, Conor M., Jeffery, C. Simon, Tout, Christopher A., Hu, Haili
• Format: Journal Article
• Language: English
• Published: De Gruyter Open 20.12.2017; De Gruyter
• Subjects: atomic processes; stars: evolution; stars: subdwarfs
• ISSN: 2543-6376; 2543-6376
• DOI: 10.1515/astro-2017-0440

Diffusion of elements in the atmosphere of a star can drastically affect its surface composition, sometimes leading to unusual mixtures. These chemically peculiar stars can be identified fromthe presence of unusual lines in their spectra. Some hot subdwarf stars show extraordinary abundances of elements such as lead, zirconium and strontium, while the abundance of helium ranges from practically zero to almost 100 percent across the hot subdwarf population. A sequence of extreme horizontal branch star models was generated by producing a number of post-common envelope objects from red giants. The evolution of these subdwarf progenitors was computed with the MESA stellar evolution code from immediately after envelope ejection right up to the ignition of helium in the core. Envelope abundances were calculated at the zero age horizontal branch for models both with and without the presence of diffusion. A small number of simulations also looked at the effects on radiative levitation of these abundances, to test how well diffusion physics is able to reproduce observational data.