Math 9071: Teichmuller and Nielsen-Thurston Theory
Spring 2017
| Meets: | Tue/Thu 2:00 - 3:200 in Wachman Hall, room 1036 |
| Instructor: | David Futer |
| Office: | 1026 Wachman Hall |
| Office Hours: | by appointment |
| E-mail: | dfuter at temple.edu |
| Phone: | (215) 204-7854 |
Course content: This course will focus on the symmetry groups of manifolds and cell complexes. We will look at both the geometric and algebraic properties of the mapping class group, which can roughly be thought of as the group of symmetries of a surface. One of the ways in which we will study the group is by designing a certain cell complex on which it acts by isometries. This principle has wide generalizations: one can derive a great deal of information about a group by constructing a geometric object for the group to act on.
In the spring semester, we will focus our attention on the braid groups, which are a special class of mapping class groups. In particular, we will study the representation theory of these groups, with connections to invariants of knots and links.
Textbooks:
- A Primer on Mapping Class Groups, by Benson Farb and Dan Margalit.
- Automorphisms of Surfaces after Nielsen and Thurston, by Andrew Casson and Steven Bleiler
Grading: Grades will be assigned based on homework and a presentation toward the end of the semester.
Detailed schedule
| Day | Topic | Reading | Homework/Note |
|---|---|---|---|
| 1/17 | Residual finiteness | P. 177-181 | See Alperin paper |
| 1/19 | Torsion | P. 200-203 | |
| 1/24 | Orbifold basics | P.203-206 | |
| 1/26 | Geometric orbifolds; Hurwitz's theorem | P. 207-210 | |
| 1/31 | Wyman's theorem; realizing finite groups | P.211-214 | |
| 2/2 | Dehn-Nielsen-Baer theorem | P.219-221, 236-238 | |
| 2/7 | Braid groups | P. 239-247 | |
| 2/9 | no class | ||
| 2/14 | Intro to Teichmuller space | P. 261-267 | |
| 2/16 | Teichmuller space via lattices | P. 269-272 | |
| 2/21 | Dimension counts; hexagons and pants | P. 272-277 | |
| 2/23 | Fenchel-Nielsen coordinates | P. 278-285 | Homework 1, due 3/2 |
| 3/2 | Teichmuller geometry | P. 294-298 | |
| 3/7 | Quasiconformal maps, measured foliations | P. 299-304 | |
| 3/9 | Singular measured foliations | P. 305-308 | |
| 3/21 | Holomorphic quadratic differentials | P. 309-313 | |
| 3/23 | The vector space of quadratic differentials | P. 314-318 | |
| 3/28 | Teichmuller maps | P. 319-324 | |
| 3/30 | Grotzcsh's theorem; Teichmuller uniqueness | P. 325-330 | |
| 4/4 | Teichmuller existence, geodesics | P. 331-339 | |
| 4/6 | Moduli space; Fricke's theorem | P. 342-351 | |
| 4/11 | Mumford's compactness criterion | P. 351-357 | |
| 4/13 | Three types of mapping classes | P. 367-369, 374-376 | |
| 4/18 | Periodic mapping classes; reducing systems | P. 370-373 | |
| 4/20 | Collar lemma; parabolic implies reducible | P. 380-385 | Homework 2, due 5/5 |
| 4/25 | Hyperbolic isometries are pseudo-Anosov | P. 385-388 | |
| 4/27 | Casson's criterion; lengths under iteration | P. 397-400, 419-422 |
dfuter at temple edu Last modified: Fri Aug 21 13:41:22 PDT 2009