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Note that the following lectures include animations and PowerPoint effects such as fly-ins and transitions that require you to be in PowerPoint's Slide Show mode (presentation mode). Chapter 12 Stellar Evolution Guidepost Stars form from the interstellar medium and reach stability fusing hydrogen in their cores. This chapter is about the long, stable middle age of stars on the main sequence and their old age as they swell to become giant stars. Here you will answer four essential questions: • Why is there a main sequence of stellar luminosities and surface temperatures? • Why is there a simple relationship between the masses and luminosities of main-sequence stars? • How does a star change as it exhausts its hydrogen? • What evidence do astronomers have that stars really do evolve? Guidepost (continued) This chapter is about how stars live. The next two chapters are about how stars die and the strange objects they leave behind. Outline I. Main-Sequence Stars A. Stellar Models B. Why is there a Main Sequence? C. The Upper End of the Main Sequence D. The Lower End of the Main Sequence E. The Life of a Main-Sequence Star F. The Life Expectancies of Stars II. Post-Main-Sequence Evolution A. Expansion into a Giant B. Degenerate Matter C. Helium Fusion D. Fusing Elements Heavier than Helium Outline (continued) III. Star Clusters: Evidence of Evolution A. Observing Star Clusters B. The Evolution of Star Clusters IV. Variable Stars: Evidence of Evolution A. Cepheid and RR Lyrae Variable Stars B. Pulsating Stars C. Period Changes in Variable Stars Stellar Models The structure and evolution of a star is determined by the laws of • Hydrostatic equilibrium • Energy transport • Conservation of mass • Conservation of energy A star’s mass (and chemical composition) completely determines its properties. That’s why stars initially all line up along the main sequence. Maximum Masses of Main-Sequence Stars Mmax ~ 100 solar masses a) More massive clouds fragment into smaller pieces during star formation. b) Very massive stars lose mass in strong stellar winds Example: Eta Carinae: Binary system of a 60 Msun and 70 Msun star Dramatic mass loss; major eruption in 1843 created double lobes Minimum Mass of Main-Sequence Stars Mmin = 0.08 Msun At masses below 0.08 Msun, stellar progenitors do not get hot enough to ignite thermonuclear fusion. Brown Dwarfs Brown Dwarfs Hard to find because they are very faint and cool; emit mostly in the infrared. Many have been detected in star forming regions like the Orion Nebula. Evolution on the Main Sequence (1) Main-Sequence stars live by fusing H to He. Zero-Age Main Sequence (ZAMS) Finite supply of H => finite life time Evolution on the Main Sequence (2) A star’s life time T ~ energy reservoir / luminosity Energy reservoir ~ M Luminosity L ~ M3.5 T ~ M/L ~ 1/M2.5 Massive stars have short lives! Evolution off the Main Sequence: Expansion into a Red Giant When the hydrogen in the core is completely converted into He: “Hydrogen burning” (i.e. fusion of H into He) ceases in the core. H burning continues in a shell around the core. He Core + H-burning shell produce more energy than needed for pressure support Expansion and cooling of the outer layers of the star Red Giant Expansion onto the Giant Branch Expansion and surface cooling during the phase of an inactive He core and a H- burning shell Sun will expand beyond Earth’s orbit! Degenerate Matter Matter in the He core has no energy source left. Not enough thermal pressure to resist and balance gravity Matter assumes a new state, called degenerate matter: Pressure in degenerate core is due to the fact that electrons can not be packed arbitrarily close together and have small energies. Red Giant Evolution H-burning shell keeps dumping He onto the core. 4 H → He He-core gets denser and hotter until the next stage of nuclear burning can begin in the core: He fusion through the “Triple-Alpha Process” He 4He + 4He 8Be + g 8Be + 4He 12C + g Helium Flash The onset of Helium fusion occurs very rapidly, in an event called the Helium Flash. Red Giant Evolution (5 solar-mass star) Helium in the core exhausted; development of He-burning shell Development of Carbon-Oxygen Core Helium ignition in the core Red giant Expansion to red giant Main Sequence Fusion Into Heavier Elements Fusion into heavier elements than C, O requires very high temperatures; occurs only in very massive stars (more than 8 solar masses). The Life “Clock” of a Massive Star (> 8 Msun) Let’s compress a massive star’s life into one day… H He 11 12 1 Life on the Main Sequence + Expansion to Red Giant: 22 h, 24 min. 2 10 9 3 4 8 H burning 7 6 5 H He He C, O 11 12 1 2 10 He burning: (Red Giant Phase) 1 h, 35 min, 53 s 9 3 4 8 7 6 5 The Life “Clock” of a Massive Star (2) H He He C, O C Ne, Na, Mg, O C burning: 6.99 s H He He C, O 11 12 1 10 9 2 3 8 4 7 6 5 C Ne, Na, Mg, O Ne O, Mg Ne burning: 6 ms 23:59:59.996 The Life “Clock” of a Massive Star (3) H He He C, O C Ne, Na, Mg, O Ne O, Mg O Si, S, P O burning: 3.97 ms H He He C, O 23:59:59.99997 C Ne, Na, Mg, O Ne O, Mg O Si, S, P Si Fe, Co, Ni Si burning: 0.03 ms The final 0.03 msec!! Summary of Post Main-Sequence Evolution of Stars Supernova Fusion proceeds; formation of Fe core. M>8 Msun Evolution of 4 - 8 Msun stars is still uncertain. Mass loss in stellar winds may reduce them all to < 4 Msun stars. Fusion stops at formation of C,O core. M < 4 Msun M < 0.4 Msun Red dwarfs: He burning never ignites Evidence for Stellar Evolution: Star Clusters Stars in a star cluster all have approximately the same age! More massive stars evolve more quickly than less massive ones. If you put all the stars of a star cluster on a HR diagram, the most massive stars (upper left) will be missing! HR Diagram of a Star Cluster Example: HR diagram of the star cluster M3 Estimating the Age of a Cluster The lower on the MS the turn-off point, the older the cluster. Evidence for Stellar Evolution: Variable Stars Some stars show intrinsic brightness variations not caused by eclipsing in binary systems. Most important example: d Cephei Light curve of d Cephei Cepheid Variables: The Period-Luminosity Relation The variability period of a Cepheid variable is correlated with its luminosity. The more luminous it is, the more slowly it pulsates. => Measuring a Cepheid’s period, we can determine its absolute magnitude! Pulsating Variables: The Instability Strip For specific combinations of radius and temperature, stars can maintain periodic oscillations. Those combinations correspond to locations in the Instability Strip Cepheids pulsate with radius changes of ~ 5 – 10 %. Period Changes in Variable Stars Periods of some Variables are not constant over time because of stellar evolution. Another piece of evidence for stellar evolution