https://wiki.math.wisc.edu/api.php?action=feedcontributions&user=Tveite&feedformat=atomUW-Math Wiki - User contributions [en]2022-11-30T03:42:51ZUser contributionsMediaWiki 1.35.6https://wiki.math.wisc.edu/index.php?title=AMS_Student_Chapter_Seminar&diff=13305AMS Student Chapter Seminar2017-02-07T20:08:47Z<p>Tveite: /* February 15, Paul Tveite */</p>
<hr />
<div>The AMS Student Chapter Seminar is an informal, graduate student-run seminar on a wide range of mathematical topics. Pastries (usually donuts) will be provided.<br />
<br />
* '''When:''' Wednesdays, 3:30 PM – 4:00 PM<br />
* '''Where:''' Van Vleck, 9th floor lounge (unless otherwise announced)<br />
* '''Organizers:''' [https://www.math.wisc.edu/~hast/ Daniel Hast], [https://www.math.wisc.edu/~mrjulian/ Ryan Julian], Cullen McDonald, [https://www.math.wisc.edu/~zcharles/ Zachary Charles]<br />
<br />
Everyone is welcome to give a talk. To sign up, please contact one of the organizers with a title and abstract. Talks are 30 minutes long and should avoid assuming significant mathematical background beyond first-year graduate courses.<br />
<br />
The schedule of talks from past semesters can be found [[AMS Student Chapter Seminar, previous semesters|here]].<br />
<br />
== Spring 2017 ==<br />
<br />
=== January 25, Brandon Alberts ===<br />
<br />
Title: Ultraproducts - they aren't just for logicians<br />
<br />
Abstract: If any of you have attended a logic talk (or one of Ivan's donut seminar talks) you may have learned about ultraproducts as a weird way to mash sets together to get bigger sets in a nice way. Something particularly useful to set theorists, but maybe not so obviously useful to the rest of us. I will give an accessible introduction to ultraproducts and motivate their use in other areas of mathematics.<br />
<br />
=== February 1, Megan Maguire ===<br />
<br />
Title: Hyperbolic crochet workshop<br />
<br />
Abstract: TBA<br />
<br />
=== February 8, Cullen McDonald ===<br />
<br />
=== February 15, Paul Tveite ===<br />
<br />
Title: Fun with Hamel Bases!<br />
<br />
Abstract: If we view the real numbers as a vector field over the rationals, then of course they have a basis (assuming the AOC). This is called a Hamel basis and allows us to do some cool things. Among other things, we will define two periodic functions that sum to the identity function.<br />
<br />
=== February 22, TBA ===<br />
<br />
=== March 1, TBA ===<br />
<br />
=== March 8, TBA ===<br />
<br />
=== March 15, TBA ===<br />
<br />
=== March 29, TBA ===<br />
<br />
=== April 5, TBA ===<br />
<br />
=== April 12, TBA ===<br />
<br />
=== April 19, TBA ===<br />
<br />
=== April 26, TBA ===<br />
<br />
=== May 3, TBA ===</div>Tveitehttps://wiki.math.wisc.edu/index.php?title=AMS_Student_Chapter_Seminar&diff=13304AMS Student Chapter Seminar2017-02-07T20:00:48Z<p>Tveite: /* February 15, TBA */</p>
<hr />
<div>The AMS Student Chapter Seminar is an informal, graduate student-run seminar on a wide range of mathematical topics. Pastries (usually donuts) will be provided.<br />
<br />
* '''When:''' Wednesdays, 3:30 PM – 4:00 PM<br />
* '''Where:''' Van Vleck, 9th floor lounge (unless otherwise announced)<br />
* '''Organizers:''' [https://www.math.wisc.edu/~hast/ Daniel Hast], [https://www.math.wisc.edu/~mrjulian/ Ryan Julian], Cullen McDonald, [https://www.math.wisc.edu/~zcharles/ Zachary Charles]<br />
<br />
Everyone is welcome to give a talk. To sign up, please contact one of the organizers with a title and abstract. Talks are 30 minutes long and should avoid assuming significant mathematical background beyond first-year graduate courses.<br />
<br />
The schedule of talks from past semesters can be found [[AMS Student Chapter Seminar, previous semesters|here]].<br />
<br />
== Spring 2017 ==<br />
<br />
=== January 25, Brandon Alberts ===<br />
<br />
Title: Ultraproducts - they aren't just for logicians<br />
<br />
Abstract: If any of you have attended a logic talk (or one of Ivan's donut seminar talks) you may have learned about ultraproducts as a weird way to mash sets together to get bigger sets in a nice way. Something particularly useful to set theorists, but maybe not so obviously useful to the rest of us. I will give an accessible introduction to ultraproducts and motivate their use in other areas of mathematics.<br />
<br />
=== February 1, Megan Maguire ===<br />
<br />
Title: Hyperbolic crochet workshop<br />
<br />
Abstract: TBA<br />
<br />
=== February 8, Cullen McDonald ===<br />
<br />
=== February 15, Paul Tveite ===<br />
<br />
Fun with Hamel Bases!<br />
<br />
=== February 22, TBA ===<br />
<br />
=== March 1, TBA ===<br />
<br />
=== March 8, TBA ===<br />
<br />
=== March 15, TBA ===<br />
<br />
=== March 29, TBA ===<br />
<br />
=== April 5, TBA ===<br />
<br />
=== April 12, TBA ===<br />
<br />
=== April 19, TBA ===<br />
<br />
=== April 26, TBA ===<br />
<br />
=== May 3, TBA ===</div>Tveitehttps://wiki.math.wisc.edu/index.php?title=AMS_Student_Chapter_Seminar,_previous_semesters&diff=13038AMS Student Chapter Seminar, previous semesters2017-01-18T21:27:18Z<p>Tveite: /* December 14, Paul Tveite */</p>
<hr />
<div>The [[AMS Student Chapter Seminar]] is an informal, graduate student-run seminar on a wide range of mathematical topics. Here are all the talks given in previous semesters.<br />
<br />
== Fall 2016 ==<br />
<br />
=== October 12, Soumya Sankar ===<br />
<br />
Title: Primes of certain forms and covering systems<br />
<br />
Abstract: A lot of classical questions revolve around primes of the form 2^n + k, where k is an odd integer. I will talk about such primes, or the lack thereof, and use this to convert coffee into covering systems. Time permitting, I'll talk about a few cool results and conjectures related to the notion of covering systems.<br />
<br />
=== October 19, Daniel Hast ===<br />
<br />
Title: A combinatorial lemma in linear algebra<br />
<br />
Abstract: I'll talk about a fun little lemma in linear algebra and its combinatorial interpretation. (It might be "well-known" to someone, but I'd never heard of it before.) If there's time, I'll discuss some possible generalizations.<br />
<br />
=== October 26, Brandon Alberts ===<br />
<br />
Title: An Introduction to Matroids<br />
<br />
Abstract: What if you wanted to do linear algebra, but couldn't use addition or scalar multiplication? Can we still have a notion of independence and bases? The answer is yes, and these are called matroids. Not only will I introduce matroids, but I will give an example that shows not all matroids arise from vector spaces.<br />
<br />
=== November 2, Vlad Matei ===<br />
<br />
Title: Hadamard Matrices<br />
<br />
Abstract: A Hadamard matrix is a square matrix whose entries are either +1 or −1 and whose rows are mutually orthogonal. The most important open question in the theory of Hadamard matrices is that of existence. The Hadamard conjecture proposes that a Hadamard matrix of order 4k exists for every positive integer k. The Hadamard conjecture has also been attributed to Paley, although it was considered implicitly by others prior to Paley's work.<br />
<br />
=== November 9, David Bruce ===<br />
<br />
Title: Some Numbers Are Sometimes Bigger Than Others (Sometimes...)<br />
<br />
Abstract: I will write down two numbers and show that one of them is larger than the other.<br />
<br />
=== November 16, Solly Parenti ===<br />
<br />
Title: The Congruent Number Problem<br />
<br />
Abstract: To add to the over-romanticization of number theory, I will talk about a simple to state problem about triangles that quickly leads into very difficult open problems in modern number theory.<br />
<br />
=== November 30, Iván Ongay Valverde ===<br />
<br />
Title: Games for fun, games to change the world, games, games, games<br />
<br />
Abstract: We will talk about infinite perfect information games. We will discuss different uses for these games, and we will see that some of them have interesting information for us that helps determine some properties of subsets of reals. Can games change the world? Can we use them in a non-intrusive way? Join to have fun with games, since they are games!<br />
<br />
=== December 7, Will Mitchell ===<br />
<br />
Title: An unsolved isomorphism problem from plane geometry<br />
<br />
Abstract: A geometric n-configuration is a collection of points and lines in the Euclidean plane such that each point lies on exactly n lines and each line passes through n points. While the study of 3-configurations dates to the nineteenth century, the first example of a 4-configuration appeared only in 1990. I will say a few things about 4-configurations and state an unsolved problem, and I hope that someone in the audience will decide to work on it. There will be nice pictures and a shout-out to the singular value decomposition.<br />
<br />
=== December 14, Paul Tveite ===<br />
<br />
Title: Infinite Chess - Mate in Infinity<br />
<br />
Abstract: There's a long history of stating puzzles using chess boards and chess pieces. Particularly endgame puzzles, like so-called "mate in n" problems. When we extend these questions to chess on an infinite board, we get some surprisingly mathematically deep answers.<br />
<br />
== Spring 2016 ==<br />
<br />
=== January 27, Wanlin Li ===<br />
<br />
Title: The Nottingham group<br />
<br />
Abstract: It's the group of wild automorphisms of the local field F_q((t)). It's a finitely generated pro-p group. It's hereditarily just infinite. Every finite p-group can be embedded in it. It's a favorite test case for conjectures concerning pro-p groups. It's the Nottingham group! I will introduce you to this nice pro-p group which is loved by group theorists and number theorists.<br />
<br />
=== February 3, Will Cocke ===<br />
<br />
Title: Who or What is the First Order & Why Should I Care?<br />
<br />
Abstract: As noted in recent films, the First Order is very powerful. We will discuss automated theorem proving software, including what exactly that means. We will then demonstrate some theorems, including previously unknown results, whose proofs can be mined from your computer.<br />
<br />
=== February 10, Jason Steinberg ===<br />
<br />
Title: Mazur's Swindle<br />
<br />
Abstract: If we sum the series 1-1+1-1+1-1+... in two ways, we get the nonsensical result 0=1 as follows: 0=(1-1)+(1-1)+(1-1)+...=1+(-1+1)+(-1+1)+...=1. While the argument is invalid in the context of adding infinitely many numbers together, there are other contexts throughout mathematics when it makes sense to take arbitrary infinite "sums" of objects in a way that these sums satisfy an infinite form of associativity. In such contexts, the above argument is valid. Examples of such contexts are connected sums of manifolds, disjoint unions of sets, and direct sums of modules, and in each case we can use this kind of argument to achieve nontrivial results fairly easily. Almost too easily...<br />
<br />
=== February 17, Zachary Charles ===<br />
<br />
Title: #P and Me: A tale of permanent complexity<br />
<br />
Abstract: The permanent is the neglected younger sibling of the determinant. We will discuss the permanent, its properties, and its applications in graph theory and commutative algebra. We will then talk about computational complexity classes and why the permanent lies at a very strange place in the complexity hierarchy. If time permits, we will discuss operations with even sillier names, such as the immanant.<br />
<br />
=== February 24, Brandon Alberts ===<br />
<br />
Title: The Rado Graph<br />
<br />
Abstract: A graph so unique, that a countably infinite random graph is isomorphic to the Rado Graph with probability 1. This talk will define the Rado Graph and walk through a proof of this surprising property.<br />
<br />
=== March 2, Vlad Matei ===<br />
<br />
Title: Pythagoras numbers of fields<br />
<br />
Abstract: The Pythagoras number of a field describes the structure of the set of squares in the field. The Pythagoras number p(K) of a field K is the smallest positive integer p such that every sum of squares in K is a sum of p squares.<br />
<br />
A pythagorean field is one with Pythagoras number 1: that is, every sum of squares is already a square. <br />
<br />
These fields have been studied for over a century and it all started with David Hilbert and his famous 17th problem and whether or not positive polynomial function on '''R'''^n can be written as a finite sum of squares of polynomial functions.<br />
<br />
We explore the history and various results and some unanswered questions.<br />
<br />
=== March 9, Micky Steinberg ===<br />
<br />
Title: The Parallel Postulate and Non-Euclidean Geometry.<br />
<br />
Abstract:<br />
“Is Euclidean Geometry true? It has no meaning. We might as well ask if the metric system is true and if the old weights and measures are false; if Cartesian coordinates are true and polar coordinates false. One geometry cannot be more true than another: it can only be more convenient.” -Poincaré<br />
<br />
Euclid’s Fifth Postulate is logically equivalent to the statement that there exists a unique line through a given point which is parallel to a given line. For 2000 years, mathematicians were sure that this was in fact a theorem which followed from his first four axioms. In attempts to prove the postulate by contradiction, three mathematicians accidentally invented a new geometry...<br />
<br />
=== March 16, Keith Rush ===<br />
<br />
Title: Fourier series, random series and Brownian motion--the beginnings of modern analysis and probability<br />
<br />
Abstract: A mostly historical and (trust me!) non-technical talk on the development of analysis and probability through the interplay between a few fundamental, well-known objects: namely Fourier, random and Taylor series, and the Brownian Motion. In my opinion this is a beautiful and interesting perspective that deserves to be better known. DISCLAIMER: I'll need to end at least 5 minutes early because I'm giving the grad analysis talk at 4.<br />
<br />
=== March 30, Iván Ongay Valverde ===<br />
<br />
Title: Monstrosities out of measure<br />
<br />
Abstract: It is a well known result that, using the Lebesgue measure, not all subsets of the real line are measurable. To get this result we use the property of invariance under translation and the axiom of choice. Is this still the case if we remove the invariance over translation? Depending how we answer this question the properties of the universe itself can change.<br />
<br />
=== April 6, Nathan Clement ===<br />
<br />
Title: Algebraic Doughnuts<br />
<br />
Abstract: A fun, elementary problem with a snappy solution from Algebraic Geometry. The only prerequisite for this talk is a basic knowledge of circles!<br />
<br />
=== April 13, Adam Frees ===<br />
<br />
Title: The proof is in the 'puting: the mathematics of quantum computing<br />
<br />
Abstract: First proposed in the 1980s, quantum computing has since been shown to have a wide variety of practical applications, from finding molecular energies to breaking encryption schemes. In this talk, I will give an introduction to quantum mechanics, describe the basic building blocks of a quantum computer, and (time permitting) demonstrate a quantum algorithm. No prior physics knowledge required!<br />
<br />
=== April 20, Eva Elduque ===<br />
<br />
Title: The Cayley-Hamilton Theorem<br />
<br />
Abstract: The Cayley-Hamilton Theorem states that every square matrix with entries in a commutative ring is a root of its characteristic polynomial. We all have used this theorem many times but might have never seen a proof of it. In this talk I will give a slick proof of this result that uses density and continuity so as to prevent the non-algebraists in the room from rioting.<br />
<br />
=== April 27, David Bruce ===<br />
<br />
Title: A Crazy Way to Define Homology<br />
<br />
Abstract: This talk will be like a costume party!! However, instead of pretending to be an astronaut I will pretend to be a topologist, and try and say something about the Dold-Thom theorem, which gives a connected between the homotopy groups and homology groups of connected CW complexes. So I guess this talk will be nothing like a costume party, but feel free to wear a costume if you want.<br />
<br />
=== May 4, Paul Tveite ===<br />
<br />
Title: Kissing Numbers (not the fun kind)<br />
<br />
Abstract: In sphere packing, the n-dimensional kissing number is the maximal number of non-intersecting radius 1 n-spheres that can all simultaneously be tangent to a central, radius 1 n-sphere. We'll talk a little bit about the known solutions and some of the interesting properties that this problem has.<br />
<br />
=== May 11, Becky Eastham ===<br />
<br />
Title: Logic is Useful for Things, Such as Ramsey Theory<br />
<br />
Abstract: Hindman’s Theorem, first proven in 1974, states that every finite coloring of the positive integers contains a monochromatic IP set (a set of positive integers which contains all finite sums of distinct elements of some infinite set). The original proof was long, complicated, and combinatorial. However, there’s a much simpler proof of the theorem using ultrafilters. I’ll tell you what an ultrafilter is, and then I will, in just half an hour, prove Hindman’s Theorem by showing the existence of an idempotent ultrafilter.<br />
<br />
== Fall 2015 ==<br />
<br />
=== October 7, Eric Ramos ===<br />
<br />
Title: Configuration Spaces of Graphs<br />
<br />
Abstract: A configuration of n points on a graph is just a choice of n distinct points. The set of all such configurations is a topological space, and so one can study its properties. Unsurprisingly, one can determine a lot of information about this configuration space from combinatorial data of the graph. In this talk, we consider some of the most basic properties of these spaces, and discuss how they can be applied to things like robotics. Note that most of the talk will amount to drawing pictures until everyone agrees a statement is true.<br />
<br />
=== October 14, Moisés Herradón ===<br />
<br />
Title: The natural numbers form a field<br />
<br />
Abstract: But of course, you already knew that they form a field: you just have to biject them into Q and then use the sum and product from the rational numbers. However, out of the many field structures the natural numbers can have, the one I’ll talk about is for sure the cutest. I will discuss how this field shows up in "nature" (i.e. in the games of some fellows of infinite jest) and what cute properties it has.<br />
<br />
=== October 21, David Bruce ===<br />
<br />
Title: Coverings, Dynamics, and Kneading Sequences<br />
<br />
Abstract: Given a continuous map f:X—>X of topological spaces and a point x in X one can consider the set {x, f(x), f(f(x)), f(f(f(x))),…} i.e, the orbit of x under the map f. The study of such things even in simple cases, for example when X is the complex numbers and f is a (quadratic) polynomial, turns out to be quite complex (pun sort of intended). (It also gives rise to main source of pretty pictures mathematicians put on posters.) In this talk I want to show how the study of such orbits is related to the following question: How can one tell if a (ramified) covering of S^2 comes from a rational function? No background will be assumed and there will be pretty pictures to stare at.<br />
<br />
=== October 28, Paul Tveite ===<br />
<br />
Title: Gödel Incompleteness, Goodstein's Theorem, and the Hydra Game<br />
<br />
Abstract: Gödel incompleteness states, roughly, that there are statements about the natural numbers that are true, but cannot be proved using just Peano Arithmetic. I will give a couple concrete examples of such statements, and prove them in higher mathematics.<br />
<br />
=== November 4, Wanlin Li ===<br />
<br />
Title: Expander Families, Ramanujan graphs, and Property tau<br />
<br />
Abstract: Expander family is an interesting topic in graph theory. I will define it, give non-examples and talk about the ideal kind of it, i.e. Ramanujan graph. Also, I will talk about property tau of a group and how it is related to expander families. To make the talk not full of definitions, here are part of the things I'm not going to define: Graph, regular graph, Bipartite graph, Adjacency matrix of a graph and tea...<br />
<br />
=== November 11, Daniel Hast ===<br />
<br />
Title: Scissor groups of polyhedra and Hilbert's third problem<br />
<br />
Abstract: Given two polytopes of equal measure (area, volume, etc.), can the first be cut into finitely many polytopic pieces and reassembled into the second? To investigate this question, we will introduce the notion of a "scissor group" and compute the scissor group of polygons. We will also discuss the polyhedral case and how it relates to Dehn's solution to Hilbert's third problem. If there is time, we may mention some fancier examples of scissor groups.<br />
<br />
=== November 18, James Waddington ===<br />
<br />
''Note: This week's talk will be from 3:15 to 3:45 instead of the usual time.''<br />
<br />
Title: Euler Spoilers<br />
<br />
Abstract: Leonhard Euler is often cited as one of the greatest mathematicians of the 18. Century. His solution to the Königsburg Bridge problem is an important result of early topology. Euler also did work in combinatorics and in number theory. Often his methods tended to be computational in nature (he was a computer in the traditional sense) and from these he proposed many conjectures, a few of which turned out to be wrong. Two failed conjectures of Euler will be presented.<br />
<br />
=== December 9, Brandon Alberts ===<br />
<br />
Title: The field with one element<br />
<br />
=== December 16, Micky Soule Steinberg ===<br />
<br />
Title: Intersective polynomials<br />
<br />
==Spring 2015==<br />
<br />
===January 28, Moisés Herradón===<br />
<br />
Title: Winning games and taking names<br />
<br />
Abstract: So let’s say we’re already amazing at playing one game (any game!) at a time and we now we need to play several games at once, to keep it challenging. We will see that doing this results in us being able to define an addition on the collection of all games, and that it actually turns this collection into a Group. I will talk about some of the wonders that lie within the group. Maybe lions? Maybe a field containing both the real numbers and the ordinals? For sure it has to be one of these two!<br />
<br />
===February 11, Becky Eastham===<br />
<br />
Title: A generalization of van der Waerden numbers: (a, b) triples and (a_1, a_2, ..., a_n) (n + 1)-tuples<br />
<br />
Abstract: Van der Waerden defined w(k; r) to be the least positive integer such that for every r-coloring of the integers from 1 to w(k; r), there is a monochromatic arithmetic progression of length k. He proved that w(k; r) exists for all positive k, r. I will discuss the case where r = 2. These numbers are notoriously hard to calculate: the first 6 of these are 1, 3, 9, 35, 178, and 1132, but no others are known. I will discuss properties of a generalization of these numbers, (a_1, a_2, ..., a_n) (n + 1)-tuples, which are sets of the form {d, a_1x + d, a_2x + 2d, ..., a_nx + nd}, for d, x positive natural numbers.<br />
<br />
===February 18, Solly Parenti===<br />
<br />
Title: Chebyshev's Bias<br />
<br />
Abstract: Euclid told us that there are infinitely many primes. Dirichlet answered the question of how primes are distributed among residue classes. This talk addresses the question of "Ya, but really, how are the primes distributed among residue classes?" Chebyshev noted in 1853 that there seems to be more primes congruent to 3 mod 4 than their are primes congruent to 1 mod 4. It turns out, he was right, wrong, and everything in between. No analytic number theory is presumed for this talk, as none is known by the speaker.<br />
<br />
===February 25, David Bruce===<br />
<br />
Title: Mean, Median, and Mode - Well Actually Just Median<br />
<br />
Abstract: Given a finite set of numbers there are many different ways to measure the center of the set. Three of the more common measures, familiar to any middle school students, are: mean, median, mode. This talk will focus on the concept of the median, and why in many ways it's sweet. In particular, we will explore how we can extend the notion of a median to higher dimensions, and apply it to create more robust statistics. It will be awesome, and there will be donuts.<br />
<br />
===March 4, Jing Hao===<br />
<br />
Title: Error Correction Codes<br />
<br />
Abstract: In the modern world, many communication channels are subject to noise, and thus errors happen. To help the codes auto-correct themselves, more bits are added to the codes to make them more different from each other and therefore easier to tell apart. The major object we study is linear codes. They have nice algebraic structure embedded, and we can apply well-known algebraic results to construct 'nice' codes. This talk will touch on the basics of coding theory, and introduce some famous codes in the coding world, including several prize problems yet to be solved!<br />
<br />
===March 10 (Tuesday), Nathan Clement===<br />
<br />
''Note: This week's seminar will be on Tuesday at 3:30 instead of the usual time.''<br />
<br />
Title: Two Solutions, not too Technical, to a Problem to which the Answer is Two<br />
<br />
Abstract: A classical problem in Algebraic Geometry is this: Given four pairwise skew lines, how many other lines intersect all of them. I will present some (two) solutions to this problem. One is more classical and ad hoc and the other introduces the Grassmannian variety/manifold and a little intersection theory.<br />
<br />
===March 25, Eric Ramos===<br />
<br />
Title: Braids, Knots and Representations<br />
<br />
Abstract: In the 1920's Artin defined the braid group, B_n, in an attempt to understand knots in a more algebraic setting. A braid is a certain arrangement of strings in three-dimensional space. It is a celebrated theorem of Alexander that every knot is obtainable from a braid by identifying the endpoints of each string. Because of this correspondence, the Jones and Alexander polynomials, two of the most important knot invariants, can be described completely using the braid group. In fact, Jones was able to show that knot invariants can often be realized as characters of special representations of the braid group.<br />
<br />
The purpose of this talk is to give a very light introduction to braid and knot theory. The majority of the talk will be comprised of drawing pictures, and nothing will be treated rigorously.<br />
<br />
===April 8, James Waddington===<br />
<br />
Title: Goodstein's Theorem<br />
<br />
Abstract: One of the most important results in the development of mathematics are<br />
Gödel's Incompleteness theorems. The first incompleteness theorem shows that no<br />
list of axioms one could provide could extend number theory to a complete and<br />
consistent theory. The second showed that one such statement was no<br />
axiomatization of number theory could be used to prove its own consistency.<br />
Needless to say this was not viewed as a very natural independent statement<br />
from arithmetic. <br />
<br />
Examples of non-metamathematical results that were independent of PA, but true<br />
of second order number theory, were not discovered until much later. Within a<br />
short time of each three such statements that were more "natural" were<br />
discovered. The Paris–Harrington Theorem, which was about a statement in Ramsey<br />
theory, the Kirby–Paris theorem, which showed the independence of Goodstein's<br />
theorem from Peano Arithmetic and the Kruskal's tree theorem, a statement about<br />
finite trees. <br />
<br />
In this talk I shall discuss Goodstein's theorem which discusses the end<br />
behavior of a certain "Zero player" game about k-nary expansions of numbers.<br />
I will also give some elements of the proof of the Kirby–Paris theorem.<br />
<br />
===April 22, William Cocke===<br />
<br />
Title: Finite Groups aren't too Square<br />
<br />
Abstract: We investigate how many non-p-th powers a group can have for a given prime p.<br />
We will show using some elementary group theory, that if np(G) is the number of non-p-th powers<br />
in a group G, then G has order bounded by np(G)(np(G)+1). Time permitting we will show this bound<br />
is strict and that mentioned results involving more than finite groups.<br />
<br />
==Fall 2014==<br />
<br />
===September 25, Vladimir Sotirov===<br />
<br />
Title: [[Media:Compact-openTalk.pdf|The compact open topology: what is it really?]]<br />
<br />
Abstract: The compact-open topology on the space C(X,Y) of continuous functions from X to Y is mysteriously generated by declaring that for each compact subset K of X and each open subset V of Y, the continous functions f: X->Y conducting K inside V constitute an open set. In this talk, I will explain the universal property that uniquely determines the compact-open topology, and sketch a pretty constellation of little-known but elementary facts from domain theory that dispell the mystery of the compact-open topology's definition.<br />
<br />
===October 8, David Bruce===<br />
<br />
Title: Hex on the Beach<br />
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Abstract: The game of Hex is a two player game played on a hexagonal grid attributed in part to John Nash. (This is the game he is playing in /A Beautiful Mind./) Despite being relatively easy to pick up, and pretty hard to master, this game has surprising connections to some interesting mathematics. This talk will introduce the game of Hex, and then explore some of these connections. *As it is a lot more fun once you've actually played Hex feel free to join me at 3:00pm on the 9th floor to actually play a few games of Hex!*<br />
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===October 22, Eva Elduque===<br />
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Title: The fold and one cut problem<br />
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Abstract: What shapes can we get by folding flat a piece of paper and making (only) one complete straight cut? The answer is surprising: We can cut out any shape drawn with straight line segments. In the talk, we will discuss the two methods of approaching this problem, focusing on the straight skeleton method, the most intuitive of the two.<br />
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===November 5, Megan Maguire===<br />
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Title: Train tracks on surfaces<br />
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Abstract: What is a train track, mathematically speaking? Are they interesting? Why are they interesting? Come find out!<br />
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===November 19, Adrian Tovar-Lopez===<br />
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Title: Hodgkin and Huxley equations of a single neuron<br />
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===December 3, Zachary Charles===<br />
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Title: Addition chains: To exponentiation and beyond<br />
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Abstract: An addition chain is a sequence of numbers starting at one, such that every number is the sum of two previous numbers. What is the shortest chain ending at a number n? While this is already difficult, we will talk about how addition chains answer life's difficult questions, including: How do we compute 2^4? What can the Ancient Egyptians teach us about elliptic curve cryptography? What about subtraction?</div>Tveite