Georgia Institute of Technology College of Sciences

We give a breezy overview of Teichmuller theory, the deformation theory of Riemann surfaces. The richness of the subject comes from all the perspectives one can take on Riemann surfaces: complex analytic for sure, but also Riemannian, topological, dynamical and algebraic.  In the past 40 years or so, interest has erupted in an extension of Teichmuller theory, here thought of as a component of the character variety of surface group representations into PSL(2,\R), to the study of the character variety of surface group representations into higher rank Lie groups (e.g. SL(n, \R)). We give an even breezier discussion of that.  The whole point will be to gauge interest in topics for a followup lecture series in the spring.

We will start with a presentation by Elanor Moore and continue with a free discussion.

The classical Laudenbach-Poénaru theorem states that any diffeomorphism of $\#_n S^1 \times S^2$ extends over the boundary connect sum of $n$ $S^1 \times B^3$'s. This implies the familiar fact that in Kirby diagrams for closed 4 manifolds, you do not need to specify the attaching spheres for 3 handles; it is also the backbone result of trisection theory, which allows one to describe a closed 4 manifold by three cut systems of curves on a surface. We extend this result to the case of infinite 4-dimensional 1-handlebodies, with an eye towards developing trisections for noncompact 4 manifolds. The proof is geometric and based on extending the recent proof of Laudenbach-Poenaru due to Meier and Scott.

A graph is chordal if each of its cycles of length at least four has a chord. Chordal graphs occupy an extreme end of a trade-off between structure and generalization: they have strong structure and admit many interesting characterizations, but this strong structure makes them a special case, representative of only a few graphs. In this talk, I'll discuss a new class of graphs called locally chordal graphs. Locally chordal graphs are more general than chordal graphs, but still have enough structure to admit interesting characterizations. In particular, most of the major characterizations of chordal graphs generalize to locally chordal graphs in natural and powerful ways. In addition to explaining these characterizations, I’ll discuss some ideas about how locally chordal graphs relate to new width parameters and to results in structural sparsity. This talk is based on joint work with Paul Knappe and Jonas Kobler.