Chemical evolution with radial mixing
ArXiv 0809.3006 (2008)
Authors:
Ralph Schoenrich, James Binney
Abstract:
Models of the chemical evolution of our Galaxy are extended to include radial
migration of stars and flow of gas through the disc. The models track the
production of both iron and alpha elements. A model is chosen that provides an
excellent fit to the metallicity distribution of stars in the Geneva-Copenhagen
survey (GCS) of the solar neighbourhood, and a good fit to the local Hess
diagram. The model provides a good fit to the distribution of GCS stars in the
age-metallicity plane although this plane was not used in the fitting process.
Although this model's star-formation rate is monotonic declining, its disc
naturally splits into an alpha-enhanced thick disc and a normal thin disc. In
particular the model's distribution of stars in the ([O/Fe],[Fe/H]) plane
resembles that of Galactic stars in displaying a ridge line for each disc. The
thin-disc's ridge line is entirely due to stellar migration and there is the
characteristic variation of stellar angular momentum along it that has been
noted by Haywood in survey data. Radial mixing of stellar populations with high
sigma_z from inner regions of the disc to the solar neighbourhood provides a
natural explanation of why measurements yield a steeper increase of sigma_z
with age than predicted by theory. The metallicity gradient in the ISM is
predicted to be steeper than in earlier models, but appears to be in good
agreement with data for both our Galaxy and external galaxies. The models are
inconsistent with a cutoff in the star-formation rate at low gas surface
densities. The absolute magnitude of the disc is given as a function of time in
several photometric bands, and radial colour profiles are plotted for
representative times.
