|Name: ________________________||DUE 11/08||ID number: ________________________|
Suppose a high-mass star starts out with a mass of 20.0 M, of which 75% is hydrogen (H) and 25% is helium (He). By the end of its life, the star has the structure shown in the diagram at right, with an iron (Fe) core of 1.4 M, surrounded by 0.6 M of sulfur (S), 1.5 M of oxygen (O), 2.5 M of helium, and 14.0 M of unburned fuel.
1. During the star's life, how much iron was produced by nuclear reactions? Give your answer in units of solar mass (M).
2. How much sulfur was produced by nuclear reactions? (Hint: some of this sulfer was later `burned' to produce the iron.)
3. How much oxygen was produced by nuclear reactions?
4. How much helium was produced by nuclear reactions in the star? (Hint: keep in mind the star's initial composition!)
At each stage of nuclear burning, a tiny fraction of the mass is converted to energy. The table below lists the fractions converted at each stage in the sequence of nuclear reactions which take place in this star.
|Reaction||4H -> He||4He -> O||2O -> S||2S -> Fe|
For example, when 1 M of iron is produced by the reaction 2S -> Fe , just 0.00030 M of mass is converted to energy. (These fractions are small enough to be safely ignored in describing the star's final structure; that's why the star's final mass adds up to exactly 20.0 M).
5. During the star's life, how much mass was converted to energy by the reaction 2S -> Fe ?
6. How much mass was converted to energy by the reaction 2O -> S ?
7. How much mass was converted to energy by the reaction 4He -> O ?
8. How much mass was converted to energy by the reaction 4H -> He ?
9. Finally, when the iron core collapses, gravity converts 0.2 M of mass to energy. How does this compare to the total amount of mass converted to energy by nuclear reactions?