Near Miss abc-Triples in General Number Fields / 一般の数体におけるニアミスabc3つ組

Kawaguchi, Yuki

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21538号 / 理博第4445号 / 新制||理||1639(附属図書館) / 京都大学大学院理学研究科数学・数理解析専攻 / (主査)教授 望月 新一, 教授 向井 茂, 教授 玉川 安騎男 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

analytic number theory

abc-triple

abc conjecture

prime ideal theorem

400

The distribution of rational points on some projective varieties

Dehnert, Fabian

04 March 2019

No description available.

510

Hardy-Littlewood Method

Manin's Conjecture

Distibution of rational points

Bihomogeneous varieties

Analytic number theory

Mathematics (PPN61756535X)

Problems with power-free numbers and Piatetski-Shapiro sequences

Bongiovanni, Alex

15 April 2021

No description available.

Mathematics

exponential sums

analytic number theory

power-free numbers

piatetski-shapiro sequences

divisor sums

A Reformulation of the Delta Method and the Subconvexity Problem

Leung, Wing Hong

10 August 2022

No description available.

Mathematics

Analytic number theory

L functions

automorphic forms

the Delta method

subconvexity

Quantum Unique Ergodicity

Second moment of the central values of the symmetric square L-functions

Lam, Wing Chung

19 May 2015

No description available.

Mathematics

An Intrinsic Theory of Smooth Automorphic Representations

Moore, Daniel Ross

02 August 2018

No description available.

Mathematics

analytic number theory

automorphic representation theory

Schwartz functions

Casselman-Wallach

Systems of forms in many variables

Myerson, Simon L. Rydin

January 2016

We consider systems of polynomial equations and inequalities to be solved in integers. By applying the circle method, when the number of variables is large and the system is geometrically well-behaved we give an asymptotic estimate for the number of solutions of bounded size. In the case of R homogeneous equations having the same degree d, a classic theorem of Birch provides such an estimate provided the number of variables is R(R+1)(d-1)2^d-1+R or greater and the system is nonsingular. In many cases this conclusion has been improved, but except in the case of diagonal equations the number of variables needed has always grown quadratically in R. We give a result requiring only d2^dR+R variables, obtaining linear growth in R. When d = 2 or 3 we require only that the system be nonsingular; when d<4 we require that the coefficients of the equations belong to a certain explicit Zariski open set. These conditions are satisfied for typical systems of equations, and can in principle be checked algorithmically for any particular system. We also give an asymptotic estimate for the number of solutions to R polynomial inequalities of degree d with real coefficients, in the same number of variables and satisfying the same geometric conditions as in our work on equations. Previously one needed the number of variables to grow super-exponentially in the degree d in order to show that a nontrivial solution exists.

Předstírající přístup k analytické teorii čísel / Pretentious approach to analytic number theory

Čech, Martin

January 2018

The goal of this thesis is to present the pretentious approach to analytic number theory recently developed by Granville, Soundararajan, and others. In the first four chapters, we show the classical proof of the prime number theo- rem. We then develop the pretentious approach, explain its differences, advan- tages, and disadvantages and present another proof of the prime number theorem based on Hal'asz's theorem. This theorem is then proven using new techniques of Granville, Harper, and Soundararajan, which are substantially easier than the previous proofs. In the last chapter, we show how pretentious techniques can be used to obtain more intuitive proofs of other classical theorems or obtain new results. 1

Properties of SU(2, 1) Hecke-Maass cusp forms and Eisenstein series

Nowland, Kevin John

January 2018

No description available.

Mathematics

analytic number theory

unitary groups

Eisenstein series

Hecke-Maass forms

Maass forms

cusp forms

functional equation

Analysis in fractional calculus and asymptotics related to zeta functions

Fernandez, Arran

January 2018

This thesis presents results in two apparently disparate mathematical fields which can both be examined -- and even united -- by means of pure analysis. Fractional calculus is the study of differentiation and integration to non-integer orders. Dating back to Leibniz, this idea was considered by many great mathematical figures, and in recent decades it has been used to model many real-world systems and processes, but a full development of the mathematical theory remains incomplete. Many techniques for partial differential equations (PDEs) can be extended to fractional PDEs too. Three chapters below cover my results in this area: establishing the elliptic regularity theorem, Malgrange-Ehrenpreis theorem, and unified transform method for fractional PDEs. Each one is analogous to a known result for classical PDEs, but the proof in the general fractional scenario requires new ideas and modifications. Fractional derivatives and integrals are not uniquely defined: there are many different formulae, each of which has its own advantages and disadvantages. The most commonly used is the classical Riemann-Liouville model, but others may be preferred in different situations, and now new fractional models are being proposed and developed each year. This creates many opportunities for new research, since each time a model is proposed, its mathematical fundamentals need to be examined and developed. Two chapters below investigate some of these new models. My results on the Atangana-Baleanu model proposed in 2016 have already had a noticeable impact on research in this area. Furthermore, this model and the results concerning it can be extended to more general fractional models which also have certain desirable properties of their own. Fractional calculus and zeta functions have rarely been united in research, but one chapter below covers a new formula expressing the Lerch zeta function as a fractional derivative of an elementary function. This result could have many ramifications in both fields, which are yet to be explored fully. Zeta functions are very important in analytic number theory: the Riemann zeta function relates to the distribution of the primes, and this field contains some of the most persistent open problems in mathematics. Since 2012, novel asymptotic techniques have been applied to derive new results on the growth of the Riemann zeta function. One chapter below modifies some of these techniques to prove asymptotics to all orders for the Hurwitz zeta function. Many new ideas are required, but the end result is more elegant than the original one for Riemann zeta, because some of the new methodologies enable different parts of the argument to be presented in a more unified way. Several related problems involve asymptotics arbitrarily near a stationary point. Ideally it should be possible to find uniform asymptotics which provide a smooth transition between the integration by parts and stationary phase methods. One chapter below solves this problem for a particular integral which arises in the analysis of zeta functions.