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Black hole modeling and simulating

Black hole modeling and simulating. Paul Maynard. Information about stars. Stars tend to be very massive The sun contains 99.85% of all the matter in our solar system[3] Nuclear fusion occurs in center of the star Which produces light and gives of electromagnetic force.

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Black hole modeling and simulating

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  1. Black hole modeling and simulating Paul Maynard

  2. Information about stars • Stars tend to be very massive • The sun contains 99.85% of all the matter in our solar system[3] • Nuclear fusion occurs in center of the star • Which produces light and gives of electromagnetic force

  3. What is a black hole? • An object whose gravitational force is so strong not even light can escape it • Black holes are formed from dead stars Picture from [2]

  4. Black hole formation • A star is composed mainly of hydrogen • The hydrogen atoms combine with each other • This is called fusion • Fusion causes a great amount of outward force. Which counter acts the force of gravity.

  5. Example of forces of a star

  6. Black hole formation cont. • When all of the hydrogen is burn off the outward force stops. • If the star is big enough it will collapse into a black hole.

  7. Gravitational orbit equations [5]

  8. Einstein's Equation

  9. More precise equations • Minkowski space-time • Schwarzschild metric • Schwarzschild radius • Curvature

  10. Rotating Black holes

  11. Red shift

  12. C=4(pi)G(Mh)/c^2 Rc = Em (1-Ch/C)^(- ½) [7]

  13. References • [1]http://archive.ncsa.uiuc.edu/Cyberia/NumRel/BlackHoles.html • [2]http://archive.ncsa.uiuc.edu/Cyberia/NumRel/BlackHoleFormation.html • [3]http://www.solarviews.com/eng/solarsys.htm • [4]http://library.thinkquest.org/25715/formation/stellar.htm • [5]http://www.fourmilab.ch/gravitation/orbits/ • [6]http://archive.ncsa.uiuc.edu/Cyberia/NumRel/NumCrunchers2.html • [7]http://www.geekcomix.com/snh/bh/acimage.shtml • [8]http://www.astro.ku.dk/~cramer/RelViz/ • [9]http://www.astro.ku.dk/~cramer/RelViz/text/exhib4/exhib4.html

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