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Stars after the Main Sequence. Example: Betelgeuse (Alpha Orionis) A Hubble telescope Picture of Betelgeuse.

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Presentation on theme: "Stars after the Main Sequence. Example: Betelgeuse (Alpha Orionis) A Hubble telescope Picture of Betelgeuse."— Presentation transcript:

1 Stars after the Main Sequence. Example: Betelgeuse (Alpha Orionis) A Hubble telescope Picture of Betelgeuse

2 Last time, concluded that the Main Sequence lifetime of a star is strongly dependent on its mass How do we check this result?

3 The masses of Main Sequence stars increase as one goes “up” the Main Sequence 1 solar mass 2.40 solar masses

4 A young star cluster and a “more mature” one H & Chi Persei…. Contain O stars The Pleiades…no Main Sequence stars more massive than class B

5 M67-the most massive Main Sequence stars not much more massive than the Sun

6 Let’s look at the Hertzsprung-Russell diagrams of star clusters These data make sense as a sequence in age, beginning with the youngest (NGC2362) and going to the oldest (M67)

7 Betelgeuse is a red supergiant Deep in its interior is a Massive, incredibly compact Stellar remnant

8 When you look at a Main Sequence star, the appearance of it exterior tells you what it is like inside

9 In an evolved star, the appearance of the surface is not a good indicator of its deep interior

10 As cores contract, the density goes to “astronomical” levels, matter acts in funny ways Gas in this room, the “perfect gas law” PV=nRT. Pressure depends on both density and temperature Extremely dense, “degenerate” gas PV=Kn. Pressure depends only on density Demo

11 The structure of a star: a balance between gravity and gas pressure Technical term: hydrostatic equilibrium Gas pressure Self gravity

12 Major result of stellar evolution: post-main sequence stars move around on the Hertzsprung-Russell diagram

13 Old evolved stars throw off their outer layers, producing objects called planetary nebulas, revealing the weird cores

14 Another planetary nebula: M27 (we saw it during the field trip)

15 These compact cores exist….the white dwarf stars Nearby examples: Sirius B and Procyon B

16 The physics of white dwarf stars What holds them up? What determines their properties?

17 Equations give radius of white dwarf as a function of its mass What one might expect for how R depends on M mass radius

18 What the solution really is for a white dwarf star

19 Main features to note about white dwarf solution Note the size: objects with masses like the sun, but radii like the Earth The size becomes smaller with increasing mass There is an upper limit (the Chandrasekhar mass) to the mass of a white dwarf

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