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Lecture 16…Significance of the Hertzsprung Russell Diagram

Lecture 16…Significance of the Hertzsprung Russell Diagram. Understanding the Main Sequence (stars like the Sun). A statistical argument (no physics) Physical argument 1: what holds stars up? Physical argument 2: what powers the stars (where do they get their energy supply?).

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Lecture 16…Significance of the Hertzsprung Russell Diagram

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  1. Lecture 16…Significance of the Hertzsprung Russell Diagram

  2. Understanding the Main Sequence (stars like the Sun) • A statistical argument (no physics) • Physical argument 1: what holds stars up? • Physical argument 2: what powers the stars (where do they get their energy supply?)

  3. The nature of the Main Sequence #1: the MS as a Cambus Stop Many more people seen on the sidewalk near a Cambus stop than a random point

  4. The Main Sequence is a long-lived phase of stellar evolution. Stars spend a much longer time here than in other parts of the HR diagram

  5. Argument #2: What holds stars up? Demo Gravity tends to squeeze a star into ever-smaller object. What resists this tendency?

  6. Argument #3: The problem of 19th century astrophysics • What keeps the interior of the Sun and stars hot? • What provides the power source of the Sun over billions of years?

  7. The problem of the solar luminosity • Luminosity = 3.8E+26 Watts = 3.8E+26 Joules/sec • Chemical reactions (gasoline, explosives) yield of order 1E+06 Joules/kilogram • The mass of the Sun is 2E+30 kilogram, so total “store” of energy is 2E+36 Joules • This would keep the Sun burning for about 170 years!!!! Historical rather than geological times!!!!

  8. Some vastly more powerful energy source (than chemical reactions) must be occurring in the Sun and stars

  9. A microscopic view of chemical reactions: interactions of the electron cloud

  10. Nuclear reactions: interactions among the nuclei (Figure 17.2)

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