Saul Schleimer has asked me to point out two job ads for postdocs at Warwick that are still open. The deadline is soon – July 7th, and Saul is hoping some topologists will apply. They’re two year positions with light teaching loads. Here are the links:
http://www2.warwick.ac.uk/fac/sci/maths/jobs https://secure.admin.warwick.ac.uk/webjobs/jobs/academic/job26360.html
Here’s a neat trick that Charles Frohman related to me a number of years ago. I think it’s in this paper [1], though I wasn’t able to find it in there. The trick is beautifully simple, but there don’t seem to be that many applications of it. In fact, as far as I know the only application is in Frohman’s paper. Here’s the Lemma: Let 
I’m sure many readers here also read Tim Gowers’s blog, and so are aware that his long-awaited Tricki is now live. The idea is that it should serve as a mathematical problem-solving resource, and I’m very excited by its potential as a research tool. In contrast to Wikipedia, the idea of the Tricki is to organize the material by the problem that it’s used to solve.
I often find myself faced with an easily-stated problem in an area of mathematics with which I’m unfamiliar (combinatorics, say). I think the Tricki could be a comprehensive alternative to my current strategy in these situations, which is to pester someone in my department who I hope might know the answer.
But what the Tricki needs next is articles. Tim is doing a titanic job writing articles on all sorts of elementary pieces of mathematics, which I’m sure will be the kernel of a great foundation for the site, but I hope the Tricki will be more than just a resource for undergraduates struggling with their analysis homework. I reckon every research mathematician has a Tricki article in them, and so I encourage everyone out there to get busy on their article today!
Here’s a neat trick I learned a few weeks ago from Jonathan Bloom at Columbia University. Let’s say you have a description of a 3-manifold 
For the last six weeks or so, Tim Gowers and Terry Tao have been using their blogs (here and here) to carry out a very interesting experiment in large scale collaboration. Gowers chose an open problem and created a system for organizing comments that allowed anyone to contribute to the discussion. Now they seem to have solved the problem and Gowers has posted a blog entry with his thoughts on how the project went and what he learned from the experience. Following the whole project requires a lot of combinatorics background, and would probably require a good amount of time even for an expert (there are over 1000, mostly long, comments in the discussion.) But I think anyone who’s interested in using the web to enhance math research should take a look at his discussion of the experiment.
A couple of months ago I wrote about advanced positions of knots in Heegaard surfaces: Embeddings of a given knot into a Heegaard surface (usually in the 3-sphere) such that the knot is not primitive in either of the two handlebodies that make up the Heegaard splitting. (Recall that a knot in the boundary of a handlebody is primitive if it intersects the boundary of a properly embedded disk in a single point.) Today, I want to mention two updates on the subject.
Today I want to write about an application of axiomatic/iterated thin position that connects thin position very strongly to the theory of normal/almost normal surfaces. This is the application that actually got me started thinking about thin position, and which I’m writing up in paper-form as I write these posts. This will probably be my last post about thin position for a while, so before beginning my next post on axiomatic thin position, here’s a quick synopsis of what I’ve covered so far:
I asked Ian Biringer to write a few words about his recent work with Juan Souto [1], showing that for any given bound, there are finitely many “pieces” from which all non-Haken manifolds with bounded injectivity radius can be constructed. Here’s what he wrote:
The project evolved from some work that Ian Agol did for closed hyperbolic 3-manifolds that have rank = 2 and injectivity radius bounded below by some constant 
I want to continue my series of posts about axiomatic thin position by considering what it means for a path in the complex of surfaces S(M) (or any complex satisfying the same axioms) to represent an index one vertex in the complex of paths in S. (If you’re just tuning in now, you may want to first look at parts one, two, three and four.) Recall from the last post that a vertex in P(S) represents an equivalence class of oriented paths in S, i.e. a path in S, modulo face slides that do not change the complexity of the path. Edges in P(S) correspond to weak reductions/vertical face slides of paths in S. Faces in P(S) come from pairs of weak reductions that commute with each other. (Since this is a blog post, I will be vague about what that last sentence means.)
The complex of paths P(S) satisfies the three axioms that I defined in my second post so when we consider slender paths in this complex, we will be interested in index-zero and index-one vertices. Last time, I pointed out that index zero vertices in P(S) correspond to slender paths in S and that a path in S corresponding to an index-one vertex in P(S) will have exactly one weakly reducible maximum and the rest will be strongly irreducible. Today, I’d like to determine what we can say about the one weakly reducible maximum.
Not long ago, Jesse was kind enough to blog about my recent work with Cameron Gordon. Now that the preprint has finally appeared on the arXiv, I thought I’d say a few more words about what we do, and why.
The context is Gromov’s famous question about surface subgroups.
“Does every one-ended word-hyperbolic group contain a subgroup isomorphic to the fundamental group of a closed surface?”
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