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Transcript
Supernova’s By Blake Sharin Introduction • How are stars formed? • How do stars die? • Supernova’s – Type I Supernova – Type II Supernova • Neutron Stars • Black Holes How are Stars Formed? • Compromise between two forces. – Strong Nuclear Force • Star expands – Gravity • Pressure generated from thermonuclear reactions • Star contracts • Interstellar Medium – Cloud of dust and gas (sometimes visible) How are Stars Formed? (contd.) • • Stars form from the cold dark cloud of gas and dust in outer space. Some sort of disturbance causes clumps of matter to form. – Blast wave. • • Gravity pulls this matter together. Core Rotates, heats up the center. – Protostar. • Energy into radiation and thermal energy which increases temp. • Temp finally reaches 10 million K – Thermonuclear reaction (Hydrogen atoms fuse). Columns of cool interstellar hydrogen gas and dust that are also incubators for new stars How do Stars Die? • Two types of stars – Stars like our sun • Run out of hydrogen • Temperature cools, leading to its collapse • Becomes Red Giant Star • Turns into a White Dwarf Star How do Stars Die? (contd.) – Massive Stars • 8 times the mass of the sun • Similar to the death of the Sun • Starts off with a blue white color • Expands, cools, turns yellow • Pulsates for few months • Turns into Red Supergiant Star – 1,000 larger than our Sun Death of a Massive Star (contd.) • While the sun can burn helium and hydrogen to keep the star shinning, massive stars attain temperatures so great that Iron is produced in the core. • Iron is the most stable nuclei. • It is at this point where the core collapses and the imploding material produces a shock wave. • Shock wave blows the star apart and produces a Supernova. Illustration of a Massive Stars Life Cycle Type I Supernova • Caused by the collapse of a White Dwarf Star. • White Dwarf Star exceeds 1.4 solar masses, star will collapse. • Leaves no remnants behind. Type II Supernova • Similar to Type I Supernova, but these will leave behind a black hole or a neutron star. • If the mass of the core is less than 2 or 3 solar masses, it becomes a neutron star. • If the mass of the core is more than 2 or 3 solar masses, it becomes a black hole. Supernova 1987A Black Holes • Region of spacetime from which nothing can escape, even light. • It is impossible to see a black hole directly because no light can escape from them; they are black. • Inside the core, the brown disk weighs 100,000 times the mass of the sun. • Gravity is 1 million times as strong as the sun. Conclusion • www.hubblesite.org • www.scri.fsu.edu
