NTSGrad Spring 2020/Abstracts

In this talk I will talk about the relation between representation theory and arithmetic geometry. In particular, I will try to discuss several examples that connect representation theory and arithmetic geometry closely. Then if time permits, I will give a brief introduction to trace formula approach, which is the most powerful and promising tools in this field.

In preparation for Thursday's talk, I will review some concepts from Galois Cohomology. I will also give an introduction to the Herbrand-Ribet theorem.

I'll present some of the formalization of Shimura varieties, with a strong emphasis on examples so that we can all get a small foothold whenever someone says the term Shimura variety.

We will give some background on counting the rational points on an elliptic curve over a finite field. Then we will apply this theory to a couple of specific elliptic curves and explain how it results in (impractical) primality tests.

In 1955, Furstenberg gave a proof of the infinitude of primes by imposing a topology on Z. Under this topology, all open sets are infinite, but if you assume only finitely many primes then {1} is open. A new, similar, topology was introduced by Golomb in 1959, which turned Z^+ into a connected Hausdorff space. A general Golomb topology on a domain R was introduced by Knopfmacher and Porubský in 1997. I will draw on a paper of Clark, Lebowitz-Lockard, and Pollack, and discuss interesting properties of these topologies, and how they relate to properties of the domain R.

This talk is going to be an all-you-can-eat smorgasbord of techniques for finding rational points on curves.

We will see how results about rational points on curves can say something about integers in arithmetic progressions.

Slides

Morel and Voevodsky's A1 Homotopy Theory (c. 1998-1999) develops a homotopy theory for algebraic geometry that is analogous to the more familiar homotopy theory from algebraic topology - here, the unit interval [0,1] is replaced with the affine line A1. One concept that emerges from Morel and Voevodsky's theory is A1 Homotopy Degree, which can be defined for maps from the A1 homotopy sphere to itself. I will focus on how to compute the A1 Homotopy Degrees of such maps in a nice case, which is tractable due to work by Kass and Wickelgren (2016).

The goal of this talk is to introduce l-aidc Galois representations in various aspects, mostly related to the ones appearing in geometry through l-aidc étale cohomology of varieties. I will focus on Galois representations in two cases, finite fields and local fields.