Astronomy Assignment #1: the Sun

Astronomy Assignment #1: The Sun

Your Name______

Your Class Meeting Time ______

This assignment is due on Monday Aug 31 or Tuesday, September 01

Submit this cover sheet with your assignment.

Complete the assigned problems from the text listed below and address the Instructor Assigned Topic. Mathematical problems may be hand written. Write out the problem, show your work in solving the problem and state your answer in a complete sentence. Failure to complete all three of these tasks will result in less than full credit awarded. The Instructor assigned topic must be typed.

Read Chapter 12: Our Sun and Stellar Structure (See details at the end of this assignment)

Answer the following Review Questions:

1. What are the two main gases in the Sun? How does the Sun's mass and size compare with Jupiter?
2. What goes on in the core, Envelope (radiative zone, and convection zone) of the Sun?
3. How does nuclear fusion produce energy?
4. Why does nuclear fusion need high temperatures and densities?
5. Why is it so hard to develop nuclear fusion as a dependable power source on Earth?
6. Why will chemical reactions or gravitational contraction not work for powering the Sun?
7. What is the net result of the nuclear fusion chain process? Why does nature use the complicated chain process instead of a one-step fusion procedure?
8. Where are neutrinos produced? What information can they tell you about interior conditions in the Sun?
9. What was the solar neutrino problem? How was the problem solved and what are the implications of that solution?
10. How can you determine what the interiors of stars are like?
11. What is being equilibrated in hydrostatic equilibrium? How does hydrostatic equilibrium explain why the temperature and density increases inward toward the core of a star?
12. How does hydrostatic equilibrium control the fusion rate in the Sun?
13. What would happen to the size of a star if its core steadily produced more energy than it did at some earlier time (e.g., when a main sequence star becomes a red giant)?
14. What would happen to the size of a star if its core steadily produced less energy than it did at some earlier time (e.g., when a star stops fusing nuclei in its core)?
15. Do photons produced in the core zip right out from the Sun or does it take longer? Explain why.

Instructor Assigned Topic:

1. Answer the question below following our class lecture on how the Sun produces energy. This identical question will be on the next exam – so do it correctly now.

Describe how the Sun produces energy by describing the net proton-proton chain, as presented in class, including the origin of the particles in the net p-p chain reaction. Include the effect of thermalization on the gamma rays and a summary of the two-layer model of the Sun’s interior.

Grading Rubric:Full-credit awarded to responses that address the following points:

1. The Sun produces energy by nuclear fusion through the Proto-Proton Chain
2. Details of the reactions as covered in class:
3. Brief discussion of neutrinos
4. Brief discussion of gamma rays including thermalization
5. Brief discussion of how mass loss is associated with energy production
6. Describe the Two-Layer Model of the Sun

Reading assigned from Chapter 12 in Nick Strobel’s Astronomy Notes

1. Introduction
2. The Sun--An Average Star
3. Size
4. Composition
5. The Sun's Interior
6. The Sun's Power Source
7. Solar Luminosity---huge energy output!
8. Possible Sources of Energy
9. Gravitational Contraction Doesn't Power the Sun Long Enough
10. Nuclear Fusion Needs Extreme Temperatures and Densities
11. Some Mass is Converted to Energy in Fusion Reactions
12. Why Stars Use a Complicated Chain Reaction
13. Hydrostatic Equilibrium Controls the Reaction Rates
14. Summary
15. Neutrino
16. Description
17. Solar Neutrino Problem
18. Explorations of Neutrino Detectors
19. Interior Structure of Stars
20. Mathematical Models
21. Temperature
22. Pressure
23. Mass Density
24. Equation of State The ideal gas law relates temperature, pressure, and density.
25. Gravity Holds a Star TogetherHydrostatic Equilibrium
26. Other Pieces
27. Continuity of Mass -- conservation of mass
28. Continuity of Energy -- conservation of energy
29. Energy Transport: radiation, convection, conduction
30. Opacity: how well the gas absorbs light

1