| Tuesday, September 11 Analysis Seminar Time: 15:30 Room: MC 108 Speaker: Ilya Kossovskiy (Western) Title: Systems of PDE's associated to CR-manifolds and applications In this series of 3 talks I will first state the general concept of a system of PDE's associated to a non-degenerate CR-manifold. The idea goes back to Lie, Cartan and Segre, and it was undeservedly forgotten. The PDE-approach was recently reviewed by A.Sukhov and J.Merker and enabled the latter one to obtain some interesting results in CR-geometry. The classical results of S.Lie and the recent results of J.Merker will be stated on the second lecture. Finally, on the last lecture I will tell about a recent result with R.Shafikov concerning extension of holomorphic mappings where the PDE-approach was successfully applied as well. |
| Thursday, September 13 Algebra Seminar Time: 10:30 Room: MC 107 Speaker: Detlev Hoffmann (Dortmund) Title: Sums of squares Sums of squares have been a research topic for as long as people have studied algebra and number theory. In modern language, some of the central questions are as follows. Let R be a ring with 1. Which elements in R can be written as sums of squares of elements in R? If an element is a sum of squares, how many squares are needed to write it as such? We give a survey of a few (of the many) classical and more recent results and open problems, focusing on fields, simple (or division) algebras and commutative rings. |
Colloquium Time: 15:30 Room: MC 108 Speaker: Masoud Khalkhali (Western) Title: Weyl Law at 101 In 1911 Hermann Weyl proved his famous law on the asymptotic distribution of eigenvalues of Laplacians on a bounded domain. Answering a question posed by physicists, Lorentz and Sommerfeld among others, he showed that the statistics of large eigenvalues determines the volume and dimension of such a domain. This result, which nowadays is paraphrased as``one can hear the volume and dimension of a bounded domain", is the foundation stone of a remarkable edifice of modern mathematics known as spectral geometry. The ultimate goal is to know how much of the geometry and topology of a Riemannian manifold is encoded in its spectrum. Forexample, is it true that isospectral manifolds are isometric? That is, Can one hear the shape of a drum? While the answer is in general negative, we know that one can hear the total scalar curvature, Betti numbers, and signature  of a closed Riemannian manifold. In fact an infinite sequence of spectral invariants, known as DeWitt--Gilkey--Seeley coefficients can be defined and computed from the short time asymptotic of the heat kernel. Another set of ideas in spectral geometry concerns with different types of trace formulae and applications to number theory, quantum physics, and quantum chaos. In some sense this even goes back to the very origins of the Weyl law in quantum mechanics and in deriving Planck's radiation formula from it.In this talk I shall outline some of these connections and then focus on our current joint work with Farzad Fathizadeh and show how some of these ideas can be imported to the world of noncommutative geometry of Alain Connes. In fact without spectral geometry there could be no noncommutative geometry! In particular I shall highlight our recent proof of a Weyl law for noncommutative tori equipped with a general metric. |
| Friday, September 14 Algebra Seminar Time: 14:30 Room: MC 108 Speaker: Detlev Hoffmann (Dortmund ) Title: Differential forms, Milnor K-theory and bilinear forms under field extensions Let $F$ be a field of characteristic $p>0$, and let $X$ be an integral affine hypersurface over $F$ with function field $K=F(X)$. We determine the kernels of the restriction maps given by extending scalars from $F$ to $K$ for the following algebraic objects: the space of absolute Kahler differentials, Milnor $K$-theory modulo $p$, and the Witt ring of symmetric bilinear forms in the case $p=2$. All these kernels have a surprisingly explicit description. This is joint work by Andrew Dolphin and myself, the case of Milnor $K$-theory being due to Stephen Scully who uses our results on differential forms. |