As the ultimate stage of stellar nucleosynthesis, and the source of the iron
peak nuclei, silicon burning is important to our understanding of the evolution
of massive stars and supernovae. Our reexamination of silicon burning, using
results gleaned from simulation work done with a large nuclear network (299
nuclei and more than 3000 reactions) and from independent calculations of
equilibrium abundance distributions, offers new insights into the
quasi-equilibrium mechanism and the approach to nuclear statistical
equilibrium. We find that the degree to which the matter has been neutronized
is of great importance, not only to the final products but also to the rate of
energy generation and the membership of the quasi-equilibrium groups. A small
increase in the global neutronization results in much larger free neutron
fluences, increasing the abundances of more neutron-rich nuclei. As a result,
incomplete silicon burning results in neutron richness among the isotopes of
the iron peak much larger than the global neutronization would indicate.
Finally, we briefly discuss the limitations and pitfalls of models for silicon
burning currently employed within hydrodynamic models. In a forthcoming paper
we will present a new approximation to the full nuclear network which preserves
the most important features of the large nuclear network calculations at a
significant improvement in computational speed. Such improved methods are
ideally suited for hydrodynamic calculations which involve the production of
iron peak nuclei, where the larger network calculation proves unmanageable.Comment: 44 pages of TeX with 25 Postscript figures, uses psfig.sty, To appear
in the The Astrophysical Journal, April 1 1996. Complete PostScript version
of the paper is also available from
http://tycho.as.utexas.edu/~raph/Publications.htm