NTSGrad Fall2023/Abstracts: Difference between revisions

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| bgcolor="#F0A0A0" align="center" style="font-size:125%" |'''Hyun Jong Kim'''
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| bgcolor="#BCD2EE"  align="center" |An integral big monodromy theorem
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| bgcolor="#BCD2EE"  |Associated to a family of curves C -> S are ell-adic monodromy representations, which generalize Galois representations. I will discuss part my ongoing thesis work demonstrating a big monodromy result for the moduli space of superelliptic curves. This result uses an arithmeticity result of reduced Burau representations of Venkataramana and clutching methods of Achter and Pries. Time permitting, I will also describe applications of this big monodromy result in other parts of my thesis --- it can be used to prove a Cohen-Lenstra result for function fields and to prove a result on the vanishing of zeta functions for Kummer curves over the projective line over finite fields.
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Revision as of 13:25, 13 October 2023

This page contains the titles and abstracts for talks scheduled in the Fall 2023 semester. To go back to the main GNTS page for the semester, click here.


9/12

Joey Yu Luo
Geometric proof of Hurwitz class number relation
In this talk I will introduce the Hurwitz class number relation, and give a geometric proof using the modular curves over complex number. The main ingredients are different perspective of elliptic curves. First year graduate students who are interested in number theory are welcome.


9/19


9/26

Eiki Norizuki
Mass Formula
I will talk about a nice result by Serre which can be seen as counting the totally ramified extensions of a local field by an appropriate weight. By easy computations, one can arrive at analogous mass formulas for other extensions from Serre's mass formula. I will mention how it relates to other problems in number theory.


10/3

Caroline Nunn
Motivating class field theory
In this talk, I will give an outline of the main ideas of class field theory. I will begin by investigating the structure of the Galois group of an abelian extension of number fields using local information at unramified primes. I will then show how, in the case of cyclotomic fields, this local information can be pieced together to recover the full Galois group. This will lead us to the main results of class field theory. I will end with a number theoretic application to the problem of representing primes in the form x^2+ny^2.


10/10


10/17

Hyun Jong Kim
An integral big monodromy theorem
Associated to a family of curves C -> S are ell-adic monodromy representations, which generalize Galois representations. I will discuss part my ongoing thesis work demonstrating a big monodromy result for the moduli space of superelliptic curves. This result uses an arithmeticity result of reduced Burau representations of Venkataramana and clutching methods of Achter and Pries. Time permitting, I will also describe applications of this big monodromy result in other parts of my thesis --- it can be used to prove a Cohen-Lenstra result for function fields and to prove a result on the vanishing of zeta functions for Kummer curves over the projective line over finite fields.


10/24


10/31


11/7

TBA
TBA


11/14


11/21


11/28


12/5


12/12