* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Astronomy
History of supernova observation wikipedia , lookup
Corona Borealis wikipedia , lookup
History of Solar System formation and evolution hypotheses wikipedia , lookup
Nebular hypothesis wikipedia , lookup
Auriga (constellation) wikipedia , lookup
Formation and evolution of the Solar System wikipedia , lookup
Cassiopeia (constellation) wikipedia , lookup
Corona Australis wikipedia , lookup
Dyson sphere wikipedia , lookup
Canis Major wikipedia , lookup
Star of Bethlehem wikipedia , lookup
Astronomical spectroscopy wikipedia , lookup
Perseus (constellation) wikipedia , lookup
Aquarius (constellation) wikipedia , lookup
Stellar kinematics wikipedia , lookup
Timeline of astronomy wikipedia , lookup
Future of an expanding universe wikipedia , lookup
Cygnus (constellation) wikipedia , lookup
Corvus (constellation) wikipedia , lookup
Crab Nebula wikipedia , lookup
Orion Nebula wikipedia , lookup
IPS Astronomy: Birth and Life of a Star I. Nebulas All stars start out as a nebula A nebula is a stellar nursery A nebula is a large amount of gas and dust spread out in an immense (or big) volume Don’t get a star and a nebula confused. Nebula vs. Star Nebula – Large amount of gas in a large volume Star – Large amount of gas in a small volume Links: – Jellyfish nebula – Eskimo nebula – Horse head nebula II. Protostar: in Greek, “proto” means earliest. Protostar = earliest star Gravity pulls gas and dust in (contracts) A contracting cloud is called a protostar. Pressure and temperature increase. When the contracting gas and dust becomes so hot that nuclear fusion begins, a star is born!! – – Remember: nuclear fusion starts when hydrogen combines to form helium. During fusion, enormous amounts of energy are released. Link: Pillars of Creation nebula III. Main Sequence The star is fusing (burning) H into He (produces a lot of energy) The star is now in the “prime of its life”; it is in equilibrium. Over time; temp, luminosity, color change. Our sun is in the main sequence phase It will live for about 10 billion years Our sun is now about 4.6 billion years old – Links: Planet swallower (artist) Sun Solar prominence IV. Red Giant (or supergiant) Stars begin to die when they run out of fuel (hydrogen) The center of the star shrinks and the outer part expands The star may fuse all the elements through Fe Big, and bright, but low surface temp All stars become a red giant or a supergiant – Camera Orion – Betelgeuse and Rigel V. Death Phases of a Star A dying star will take one of three paths extinction The mass of the star dictates which path it will take After the fuel is used up, a star will become a… – White Dwarf, or – Neutron Star, or – Black Hole Path #1: White Dwarfs White Dwarfs, small stars (1 X our Sun) The outer layers of the star grow bigger and slowly drift out into space. This material rejoins a nebula to be recycled into a new star The blue-white hot core is left and the “dead” star that is left behind is a white dwarf The glow coming from the core is left-over energy from the old star. The core is NOT making any more energy. (Like turning off a light bulb) Eventually, the energy glow is gone and the core is dark. It becomes a black dwarf. – Links: Little Ghost Nebula, Helix Nebula, Eight-burst Nebula Path #2: Neutron Stars Neutron stars, medium stars (5 X our sun) A supernova occurs when a supergiant star (5 X or more our sun) suddenly explodes Some material rejoins a nebula The remaining material from the star (or core) is a neutron star Neutron stars are even smaller and more dense than white dwarfs Some neutron stars spin, these are pulsars – Links: Cosmic Pearls supernova, Elusive Jellyfish nebula (neutron star), Tycho’s Supernova Remnant, A Dark Pulsar in CTA 1, Crab Pulsar Wind Nebula Path #3: Black Holes Black holes are the most massive stars (10-40 X our sun) The (red) supergiant goes supernova, throwing the outer layers into space to rejoin a nebula The gravity of the remaining core is so strong that the core collapses in on itself, creating an even stronger gravitational pull This gravity pulls everything to it Nothing can escape its gravitational pull, not even light waves!! – Links: A view near a black hole, star ripped apart by BH, x-ray jet black hole, BH candidate Cygnus VI. Lifetimes of Stars How long a star lives depends on how much mass it has Small mass stars live longer than large mass stars – Stars that have more mass than the sun live a shorter lifetime. Approx. 10 million years – Stars that have less mass than the sun live longer. Approx. 200 billion years Example: A small car burns a gallon of gas more efficiently than a big SUV (exp 25/mpg vs 8/mpg) http://www.classzone.com/books/earth_science/terc/content/visualizations/es28 07/es2807page01.cfm?chapter_no=visualization