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Slicing up hyperbolic tetrahedra: from the infinite to the finite

Slicing up hyperbolic tetrahedra: from the infinite to the finite. Yana Mohanty. University of California, San Diego. mohanty@math.ucsd.edu. Overview. Spherical 2-D geometry. Hyperbolic 2-D geometry. Hyperbolic 3-D geometry. Hyperbolic tetrahedra. Problem statement:

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Slicing up hyperbolic tetrahedra: from the infinite to the finite

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  1. Slicing up hyperbolic tetrahedra: from the infinite to the finite Yana Mohanty University of California, San Diego mohanty@math.ucsd.edu Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  2. Overview Spherical 2-D geometry Hyperbolic 2-D geometry Hyperbolic 3-D geometry Hyperbolic tetrahedra Problem statement: Construct a finite tetrahadron out of ideal tetrahedra Motivation Study of hyperbolic 3-manifolds Scissors congruence problems Outline of method Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  3. “Lines” are great circles • Each pair of lines intersects in two points • Triangles are “plump” • Any 2-dimensional map distorts angles and/or lengths Spherical geometry Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  4. The Mercator projection: a conformal map of the sphere Angles shown are the true angles! (conformal) Areas near poles are greatly distorted Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  5. Hyperbolic geometry: the “opposite” of spherical geometry • Triangles are “skinny” • Given a point P and a line L there are many lines through P that do not intersect L. • Any 2-dimensional map distorts angles and/or lengths. A piece of a hyperbolic surface in space Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  6. lines Escher’s Circle Limit I The Poincare model of the hyperbolic plane • Preserves angles • (conformal) • Distorts lengths Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  7. Hyperbolic space LINES PLANES Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  8. metric: metric: Inversion: z>0 The Poincare and upper half-space models(obtained by inversion) z=0 Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  9. H3: The upper halfspace model(obtained by inversion) metric: “point at infinity” z>0 z=0 Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  10. Lines and planes in the half-plane model of hyperbolic space Contains point at infinity lines PLANES Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  11. Ideal tetrahedron in H3 (Poincare model) Convex hull of 4 points at the sphere at infinity Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  12. Ideal tetrahedron inH3 (half-space model) B b B b g a g C a C A A Determined by triangle ABC View from above Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  13. Hyperbolic tetrahedra ideal: 2 parameters ¾-ideal: 3 parameters finite: 6 parameters 1 or 2 ideal vertices also possible Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  14. Problem statement: How do you make out of finitely many of these? • The rules: • an ideal tetrahedron may count as + or – • use finitely many planar cuts Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  15. What is this needed for: part I Study of hyperbolic 3-manifolds 2-Manifold: An object which is homeomorphic to a plane near every one of its points. can be stretched into without tearing Example of a Euclidean 2-manifold A 2 manifold may NOT contain Can’t be stretched into a plane near this point Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  16. Euclidean 3-manifold Example: 3-Torus Glue together opposite faces Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  17. Hyperbolic 3-manifold Example: the Seifert-Weber space Drawing from Jeff Weeks’ Shape of Space Image by Matthias Weber Glue together opposite faces Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  18. A strange and amazing fact: The volume of a hyperbolic 3-manifold is a topological invariant 3-manifold Y 3-manifold X Homeomorphic (There is a continuous 1-1 map from X to Y with a continuous inverse) X and Y have the same volume Volume computation generally requires triangulating, that is, cutting up the manifold into tetrahedra. Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  19. Triangulating a hyperbolic 2-manifold Finite hyperbolic octagon 2-holed torus glue Drawing by Tadao Ito In hyperbolic space triangulation involves finite tetrahedra (6-parameters) Better: express in terms of ideal tetrahedra (2-parameters) Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  20. Example in Euclidean space: “Hill’s tetrahedron” What is this needed for: part II Solving scissors congruence problems in hyperbolic space: Given 2 polyhedra of equal volume, can one be cut up into a finite number of pieces that can be reassembled into the other one? Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  21. volume=L(g) (hidden) volume=L(b) volume=L(a) An expression for volume that also gives a canonical decompositon? Exists for ideal tetrahedra: b a V =L(a)+L(b)+L(g), g finite! where is the Lobachevsky function. Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  22. Construction of a 3/4-ideal tetrahedron out of ideal tetrahedra: extends “volume formula as a decomposition” idea to tetrahedra with finite vertex History: Algebraic Proved in 1982 by Dupont and Sah using homology. Geometric • Mentioned as unknown by W. Neumann in 1998 survey article on 3-manifolds. • Indications of construction given by Sah in 1981, but these were not well known. Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  23. rotated {a,b,c,p} p p Main idea behind proof Make a a certain type of ¾-ideal tetrahedron first d d d = + - p c c c a a b b Inspiration for choosing ideal tetrahedra: another proof of Dupont and Sah Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  24. Step 1: finite out of 1-ideal Step 2: 1-ideal out of ¾-ideal E D C B A C B A D 1-ideal finite B 1-ideal ideal ¾-ideal C A Remainder of the proof Making a finite tetrahedron out of ¾-ideal tetrahedra E C’ B’ E A’ ABCE=A’B’C’E-A’B’BE-B’C’CE-C’A’AE ABCD=ABCE-ABDE Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  25. Examples of conformal models • Spherical: Mercator projection • Hyperbolic: Poincare ball • Introduced hyperbolic tetrahedra Summary • Comparison of spherical and hyperbolic geometries Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

  26. Constructing a finite tetrahedron out of ideal ones is helpful for studying • -hyperbolic 3-manifolds • volume is an invariant, so construction is helpful in the • 3-dimensional equivalent of -scissors congruences want volume formula that is also a decomposition Summary, continued • Main ingredient: constructing a certain ¾-ideal tetrahedron • out of ideal tetrahedra. Idea comes from a proof by • Dupont and Sah. Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu

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