Key Concepts:

1. How are stars formed?
2. What is the solar nebular hypothesis?
3. What powers the luminosity of a protostar?
4. What determines the finite range of the stellar mass?
5. How do stars evolve during their "main sequence" phase?
6. How do stars meet their ends?
7. What is the ultimate fate of our Sun and the Solar System?

Sunwheel and Observatory reports due Wednesday April 1.

Stellar Birth

Astronomy Picture of the Day (2003 October 19)

• Stars form from interstellar matter -- mostly hydrogen, helium, and some dust. There are many obstacles to forming stars, however:
• ISM is really diffuse:
• particle density of water: ~10²⁴ cm^-3
• particle density of air: ~10²¹ cm^-3
• particle density of "vacuum" on Earth: ~10¹⁰ cm^-3
• particle density of "air" on the Moon: ~10¹⁰ cm^-3
• particle density of ISM: ~10¹ cm^-3
• particle density of "dense cloud": 100 to 1000 cm^-3
• conservation of angular momentum: as you shrink a gas cloud in size, it rotates faster and faster.
• Gas clouds are not uniform, and dense, small clumps collapse under its own gravity.
• Solar nebular hypothesis: conservation of angular momentum forces the collapsing cloud to form a flattened disk, and a small, hot, dense core called a protostar forms at the center.

• Cloud collapse and star formation computer simulation with turbulence (UK Astrophysical Fluids Facility and University of Leicester). Here is the movie that shows evolution of a large diffuse cloud that fragments and forms protostellar systems.
• NASA Animation of star/planet formation: this animation graphically illustrates the process of cloud collapse and formation of a protostar and a protostellar disk, and the eventual ignition of the fusion that produces a genuine star.

• a protostar is heated only by the gravitational energy of collapse alone (1500 K), and no nuclear reactions yet.
• Some million years later, the temperature rises high enough (about 7 million K) to ignite nuclear fusion, and a star is born!
• Some of the energy goes into a jet/outflow of material known as a bipolar flow.
• The leftover material continues to form the planetary system and the remnant disk.
• Stars often form in groups or in "clusters". In the same large gas cloud, massive stars and less massive stars form together.



Quiz 14A: Star formation in a Brick Oven....

• Stellar Mass Limits: (A Story of Three Bears)
• if the core has too little mass (<0.1 solar mass), not enough temperature and pressure to ignite fusion -- thus a failed star or a "brown dwarf"
• if the core has too much mass (>100 solar mass?), it becomes too hot too quickly, and strong radiation and pressure prevents additional mass from falling onto it.

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Main Sequence

• Nuclear fusion powers the main sequence stars.
• low mass stars (e.g. the Sun): hydrogen to helium (proton-proton chain)
• high mass stars: hydrogen "burning" plus CNO cycle (requires higher temperature) and Helium capture (requires even higher temperature)
• More massive stars have to be hotter (thus more luminous) to offset their larger gravity
• more massive stars have stronger gravity
• greater gravitational attraction requires greater pressure to offset it (hydrostatic equilibrium)
• greater pressure means higher temperature (perfect gas law)
• higher temperature means larger luminosity and shorter lifetime
• Quiz 14B: M1A1 vs. Mini Cooper



• Main sequence lifetime:

Low Mass Star Evolution

• When a MS star runs out of fuel (hydrogen) in its core, pressure begins to drop.
• Gravity wins again and the inner region is compressed further.
• As temperature rises, hydrogen outside the core ignites ("hydrogen shell burning").
• This shell fusion causes a widespread heating and increasing pressure. However, there is no additional pressure in the core to counter the gravitational force, despite the ongoing shell fusion, and the core continues to collapse and heats further.
• The compression and shell burning lead to increased pressure in and around the core, and this increases the luminosity of the star up to 1000 times the normal rate. This in turn causes the outer parts of the star to expand. This expansion cools the outer layer ( perfect gas law).
• Most of the mass is still in the dense core.
• Pulsating stars
• giant stars pulsate because their atmosphere trap radiated energy
• this heats outer layers, making them to expand
• expanded gas cools, pressure drops, and gravity pulls the layer back in.
• the cycle starts all over again

Death of Stars like the Sun: Planetary Nebula

• Helium flash and yellow giant phase
• helium burning ("tripple-alpha" reaction) and supergiant phase -- formation of carbon grains in the cool (1000-2000 K) photosphere
• planetary nebular: radiation pressure drives the dust grains outwards, and the outer shell becomes transparent
• a white dwarf (the naked hot core) is revealed.

Some more examples of pretty planetary nebulae

• The Hourglass Nebula
• The Eskimo Nebula
• The Cat's Eye Nebula
• The Cat's Eye Nebula (halo)
• The Ant Nebula
• NGC 6751
• The Spirograph Nebula
• M57, The Ring Nebula
• The Helix Nebula
• The Rotten Egg Nebula
• NGC 3242
• PKS 285
• He2-104

Quiz 14C: Death of the Solar System

Evolution of a Massive (>8 solar mass) Star: Supernova

"Nuclear synthesis" -- formation of heavier atoms like carbon or oxygen by fusion (Carl Sagan: "we are all star stuff") Fusion of heavier elements electric force stronger for heavier atoms, and higher temperature is needed to overcome Coulomb barrier (100 million K to fuse helium) 3 helium atoms form a carbon atom ("triple alpha process") fusing heavier atoms require higher T but less energy comes out core collapse: iron cannot burn and release energy, no more source of heat and pressure to counter gravity --> supernova either a neutron star or a black hole is formed.

Summary

Reading assignment for next lecture: Unit 64-67