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The Calculus of Black Holes

The Calculus of Black Holes. James Wang Elizabeth Lee Alina Leung Elizabeth Klinger. What is a Black Hole?. A region from which even light cannot escape Thus the black hole itself cannot be seen Detected through gravitational distortion of nearby planets and stars, and radiation

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The Calculus of Black Holes

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  1. The Calculus of Black Holes James Wang Elizabeth Lee Alina Leung Elizabeth Klinger

  2. What is a Black Hole? • A region from which even light cannot escape • Thus the black hole itself cannot be seen • Detected through gravitational distortion of nearby planets and stars, and radiation • Has infinite gravitational pull and density

  3. What is the Event Horizon? • An area around the singularity of the black hole where no particle can escape its pull • No outside influences can affect the particle’s descent towards the black hole

  4. What are Stationary Limits? • Stationary limit – area around black hole (outer border) • Particles in area are in constant motion • Rotating black hole (Kerr’s) – distortion of space • Doesn’t apply to Schwarzchild black hole – doesn’t rotate • Gravity infinitely intense • Limit between this and event horizon – ergosphere • Limit at which light can escape

  5. Diagram of a Black Hole

  6. Pictures of Black Holes

  7. How are Black Holes Modeled? • Black holes create “indentations” in space/time continuum • Curvature is the only logical way to model black holes • Black holes follow the “no-hair” theorem • Only three characteristics distinguishing black holes from one another are mass, angular momentum, and electric charge

  8. Black Holes and Einstein’s General Theory of Relativity Black Holes and Einstein’s Theory of Relativity • Gravity – curved space time • Caused by mass and radius of an object, as well as energy • Strong gravitational field = more curvature • Applies to light – light gets curved • Space affects movement of object • No material object can move faster than speed of light • Black hole – area where space time curved so much that objects fall out of the universe • Escape velocity = speed of light

  9. Maxwell’s Equations • 2nd equation: • 1st equation: • Determines total flow of electric charge out from closed surface • Cover surface with patches of area of dA (represented as vectors), use dot product to find component of field that points in outward direction (only component that matters) • Net magnetic flux is 0 • Magnetic flux – product of magnetic field and area it goes through; integral of vector quantity (magnetic force) over surface

  10. Maxwell’s Equations (cont’d) • 3rd equation: • Line integral – products of vector functions of electric and magnetic field • Equation says line integral of electric field around closed loop is equal to negative rate of change of magnetic flux

  11. Maxwell’s Equations (cont’d) • 4th equation: • Light was in form of electromagnetic wave

  12. How are Maxwell’s Equations Related to Black Holes? • Moving electric field creates magnetic vortex • Electromagnetic radiation – from charged particles that move towards black hole • Light affected by extremely strong gravity • Black hole is large magnetic field b/c electric field created when charge falls into black hole

  13. Using Riemannian Manifolds to Describe Curvature • Manifolds describe complex structures of non-Euclidian space within the context of Euclidian space using mathematical equations • Riemannian manifolds are real differentiable manifolds that use angles • Black holes are mapped into more simple structures using Riemannian manifolds

  14. Equations Modeling Black Hole Curvature The Schwarzschild Metric Equation

  15. Equations Modeling Black Hole Curvature The Schwarzschild Metric Equation (Continued)

  16. Equations for Escape Velocity and Gravitational Force • Gravitational Energy would have to equal kinetic energy • Force as mass becomes infinite and radius 0

  17. Significance of Change in Radius in Relation to Curvature • Curvature is the deviation of an object from being flat • A smaller radius has more curvature and vice versa • Therefore, black holes with smaller radii have more curvature

  18. Behavior and Emissions of a Black Hole • Electromagnetic radiation comes from charged particles that move towards black hole • Black hole is large magnetic field b/c electric field created when charge falls into black hole

  19. Photon and Gamma Particle Radiation from Black Holes • Black holes emit thermal radiation at temperature • = reduced Planck constant • c = speed of light • K = Boltzmann constant • G = gravitational constant • M = mass of black hole • Unlike most objects, the temperature of a black hole increases as it radiates away mass

  20. Gravitational Force Considerations • Black holes become impossible to escape as it approaches the event horizon as the escape velocity required, regardless of mass, equals the speed of light • Relativity, as c is constant, in order for energy to increase towards infinite, mass = infinite

  21. Bibliography • Andersen, Michael C. "Einstein's Field Equations and Black Holes." Niels Bohr Institute. 14 June 1996. Niels Bohr Institute. 14 May 2006 <http://www.astro.ku.dk/~cramer/RelViz/text/geom_web/node3.html>. • Ando, David. "An Introduction to Black Holes." 7 May 2006 <http://design.lbl.gov/education/blackholes/index.html>. • Cumberlidge, Anne-Marie. "Everything You Need to Know About Black Holes." The Hitch-Hiker's Guide to Black Holes. 1997. Keele University. 5 May 2006 <http://www.astro.keele.ac.uk/workx/blackholes/index3.html>. • "Curvature." Wikipedia. 7 May 2006 <http://en.wikipedia.org/wiki/Curvature>.

  22. Bibliography continued • Darling, David. "Euclidean Space." The Encyclopedia of Astrobiology Astronomy and Spaceflight. 12 May 2006 <http://www.daviddarling.info/encyclopedia/E/Euclidean_space.html>. • Darling, David. "Non-Euclidean Geometry." The Encyclopedia of Astrobiology Astronomy and Spaceflight. 12 May 2006 <http://www.daviddarling.info/encyclopedia/N/non-Euclidean_geometry.html>. • "Escape Velocity." Wikipedia. 7 May 2006 <http://en.wikipedia.org/wiki/Escape_velocity>. • "Euclidean Geometry." Wikipedia. 11 May 2006 <http://en.wikipedia.org/wiki/Euclidean_geometry>. • Fowler, Michael. "Maxwell's Equations and Electromagnetic Waves." 1997. Physics Dept., University of Virginia. 10 May 2006 <http://galileo.phys.virginia.edu/classes/109N/more_stuff/Maxwell_Eq.html>.

  23. Bibliography continued • "Isomorphism." Wikipedia. 15 May 2006 <http://en.wikipedia.org/wiki/Isomorphism>. • Johnston, Robert. "Black Holes." Relativistic Physics. 14 Oct. 2001. 8 May 2006 <http://www.johnstonsarchive.net/relativity/blackhole.html>. • Kobes, Randy, and Gabot Kunstatter. "Gravity as Curved Space: Einstein's Theory of General Relativity." Physics 1501 - Modern Technology. 29 Sept. 1999. University of Winnipeg. 9 May 2006 <http://theoryx5.uwinnipeg.ca/mod_tech/node60.html>. • "Manifold." Wikipedia. 15 May 2006 <http://en.wikipedia.org/wiki/Manifold>. • "Maxwell's Equations in Curved Spacetime." Wikipedia. Apr. 2006. 9 May 2006 <http://en.wikipedia.org/wiki/Maxwell%27s_equations_in_curved_spacetime>. • Nave, C.r. "Maxwell's Equations." HyperPhysics. 2005. Georgia State University. 9 May 2006 <http://hyperphysics.phy-astr.gsu.edu/HBASE/electric/maxeq.html#c2>.

  24. Bibliography continued • "Q & a: Black Holes." Chandra X-Ray Observatory. 2 Aug. 2005. Harvard University. 6 May 2006 <http://chandra.harvard.edu/resources/faq/black_hole/bhole-76.html>. • "Radius of Curvature." Wikipedia. 17 May 2006 <http://en.wikipedia.org/wiki/Radius_of_curvature>. • "Riemannian Manifold." Wikipedia. 12 May 2006 <http://en.wikipedia.org/wiki/Riemannian_manifold>. • Salgado, Rob. "The Light Cone: the Schwarzchild Black Hole." Syracuse University. 7 May 2006 <http://physics.syr.edu/courses/modules/LIGHTCONE/schwarzschild.html>. • Seeds, Michael A. Horizons: Exploring the Universe. 7th ed. Pacific Grove, CA: Brooks/Cole, 2002.

  25. Bibliography continued • Smith, Gene E. "General Relativity & Black Holes." Gene Smith's Astronomy Tutorial. 9 Mar. 2000. University of California San Diego. 17 May 2006 <http://cassfos02.ucsd.edu/public/tutorial/GR.html>. • "The Mystery of Black Holes." Knowing the Universe and Its Secrets. 7 Feb. 2006. 9 May 2006 <http://nrumiano.free.fr/Estars/b_holes.html>. • Weisstein, Eric W. "Neighborhood." MathWorld. 12 May 2006 <http://mathworld.wolfram.com/Neighborhood.html>. • Wyatt, Ryan, and Rachel Connolly. "From Einstein to Hawking Course Outline." 28 Apr. 2003. American Museum of Natural History. 10 May 2006 <http://research.amnh.org/users/wyatt/Hayden/fromEtoH.html>.

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