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Types of Stars

Types of Stars. March 2012. Stellar Classification. Is a classification of stars according to their spectral characteristics: the types of light they emit.

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Types of Stars

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  1. Types of Stars March 2012

  2. Stellar Classification Is a classification of stars according to their spectral characteristics: the types of light they emit. Most current stars are classified by the letters: O, B, A, F, G, K, and M (usually memorized by astrophysicists as "Oh, be a fine girl, kiss me") Informally, O stars are called "blue", B "blue-white", A stars "white", F stars "yellow-white", G stars "yellow", K stars "orange", and M stars "red", even though the actual star colors perceived by an observer may be different. In the Morgan-Keenan classification system, the spectrum letter is enhanced by a number from 0 to 9 indicating tenths of the range between two star classes. And a Roman Number indicating the luminosity. Our sun has a spectral type G2V and the apparently bright star Sirius has a type A1V.

  3. Stellar Evolution It is the process undergone by stars through their lifetimes. Depending on the mass of the star this can be from a few million years for the most massive to billions of years for the least massive.

  4. Stellar Evolution Contd. Stars are born from collapsing clouds of gas and dust, often called nebulae. Stars similar to our Sun gradually grow in size until they reach a red giant phase, after which the core collapses into a dense white dwarfand the outer layers are expelled as a planetary nebula. Larger stars can explode in a supernova as their cores collapse into an extremely dense neutron staror black hole. • Image of "StarBirth" Clouds in M16:PRC95-44b Hubble Wide Field Image

  5. Size comparison of celestial bodies Earth, Venus, Mars, Mercury, the Moon...

  6. Size comparison of celestial bodies Jupiter, Saturn, Uranus, Neptune, Earth, Venus, Mars, Mercury, the Moon...

  7. Size comparison of celestial bodies Sun, Jupiter, Saturn, Uranus, Neptune, Earth, Venus, Mars, Mercury...

  8. Size comparison of celestial bodies

  9. Size comparison of celestial bodies

  10. Death of an ordinary star. After a low mass star like the Sun exhausts the supply of hydrogen in its core, there is no longer any source of heat to support the core against gravity. Hydrogen burning continues in a shell around the core and the star evolves into a red giant. When the Sun becomes a red giant, its atmosphere will envelope the Earth and our planet will be consumed in a fiery death. Eventually, the Sun will lose all of the mass in its envelope and leave behind a hot core of carbon embedded in a nebula of expelled gas. Radiation from this hot core will ionize the nebula, producing a striking "planetary nebula", much like the nebulae seen around the remnants of other stars. The carbon core will eventually cool and become a white dwarf, the dense dim remnant of a once bright star. • Image of a PlanetaryNebula:NGC 6543 Hubble Wide Field Image

  11. Death of a massive star. Massive stars burn brighter and perish more dramatically than most. When a star ten times more massive than Sun exhaust the helium in the core, the nuclear burning cycle continues. The carbon core contracts further and reaches high enough temperature to burn carbon to oxygen, neon, silicon, sulfur and finally to iron. Iron is the most stable form of nuclear matter and there is no energy to be gained by burning it to any heavier element. Without any source of heat to balance the gravity, the iron core collapses until it reaches nuclear densities. This high density core resists further collapse causing the matter to "bounce" off the core. This sudden core bounce (which includes the release of energetic neutrinos from the core) produces a supernova explosion.

  12. For one brilliant month, a single star burns brighter than a whole galaxy of a billion stars. Supernova explosions inject carbon, oxygen, silicon and other heavy elements up to iron into interstellar space. Without supernova, the fiery death of massive stars, there would be no carbon, oxygen or other elements that make life possible. The fate of the hot neutron core depends upon the mass of the progenitor star. If the progenitor mass is around ten times the mass of the Sun, the star core will cool to form a neutron star. Neutron stars are potentially detectable as "pulsars", powerful beacons of radio emission. If the progenitor mass is larger, then the resultant core is so heavy that not even nuclear forces can resist the pull of gravity and the core collapses to form a black hole. • Image of a Supernova Remnant:Supernova 1987A Hubble Wide Field Image

  13. Neutron Stars Neutron stars are strange and fascinating objects. They represent an extreme state of matter that physicists are eager to know more about. The intense gravitational field would pull any spacecraft to pieces before it reached the surface. The magnetic fields around neutron stars are also extremely strong. If the neutron star is rotating rapidly, as most young neutron stars are, the strong magnetic fields combined with rapid rotation create an awesome generator that can produce electric potential differences of quadrillions of volts. Credit: NASA/CXC/ASU/J.Hester et al.

  14. Black Holes. A deep gravitational warp in space called a black hole. A black hole does not have a surface in the usual sense of the word. There is simply a region, or boundary, in space around a black hole beyond which we cannot see. This boundary is called the event horizon. Anything that passes beyond the event horizon is doomed to be crushed as it descends ever deeper into the gravitational well of the black hole. No visible light, nor X-rays, nor any other form of electromagnetic radiation, nor any particle, no matter how energetic, can escape.

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