Class field theory, its three main generalisations, and applications

IF 1.3 Q1 MATHEMATICS EMS Surveys in Mathematical Sciences Pub Date : 2021-08-31 DOI:10.4171/emss/45
I. Fesenko
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Abstract

Class Field Theory (CFT) is the main achievement of algebraic number theory of the 20th century. Its reach, beauty and power, stemming from the first steps in algebraic number theory by Gaus, have substantially influenced number theory. Shafarevich wrote: 'Weil was undoubtedly right when he asserted, in the preface to the Russian edition of his book on number theory 1 , that since class field theory pertains to the foundation of mathematics, every mathematician should be as familiar with it as with Galois theory. Moreover, just like Galois theory before it, class field theory was reputed to be very complicated and accessible only to experts ... For class field theory, on the other hand, there is a wide range of essentially different expositions, so that it is not immediately obvious even whether the subject is the same'. 2 Weil's opinion has proved to be quixotic: these days even some number theorists are not familiar with the substance of CFT. This text reviews the enduring process of discovering new branches of CFT and its generalisations. Many of such developments were complicated at their early stages and some were difficult or impossible to understand for their contemporaries. Three main generalisations of CFT and their further extensions will be presented and some of their key fundamental features will be discussed. This text proposes eight fundamental problems. We start with Kummer theory, a purely algebraic exercise, whose highly non-trivial arithmetic analogues over arithmetic fields are supplied by CFT. Kummer theory is an algebraic predecessor of CFT including its existence theorem. Then we discuss the fundamental split of (one-dimensional) CFT into special CFT (SCFT) and general CFT (GCFT). This split has enormously affected many developments in number theory. Section 3 delves into four fundamental parts of CFT including the reciprocity map, existence theorem, explicit formulas for the Hilbert symbol and its generalisations, and interaction with ramification theory. Section 4 briefly touches on higher Kummer theory using Milnor K-groups, i.e. the norm residue isomorphism property. Three generalisations of CFT: Langlands correspondences (LC), higher CFT, and anabelian geometry are discussed in section 5. We note that the split of CFT into SCFT and GCFT is currently somehow reproduced at the level of generalisations of CFT: LC over number fields does not yet have any development parallel to GCFT, while higher CFT is parallel to GCFT and it does not have substantial developments similar to SCFT. In the last section we specialise to elliptic curves over global fields, as an illustration. There we consider two further developments: Mochizuki's inter-universal Teichmuller theory (IUT) which is pivoted on anabelian geometry and two-dimensional adelic analysis and geometry which uses structures of two-dimensional CFT. We also consider the fundamental role of zeta integrals which may unite different generalisations of CFT. Similarly to the situation with LC, the current studies of special values of zeta-and L-functions of elliptic curves over number fields, except two-dimensional adelic analysis and geometry, use special structures and are not of general type. There is no attempt to mention all the main results in CFT and all of its generalisations or all of their parts, and the text does not include all of bibliographical references. 1 [64] 2 in Foreword to [13].
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类场论,它的三个主要概括和应用
类场论是20世纪代数数论的主要成果。它的范围,美丽和力量,源于高斯在代数数论的第一步,对数论产生了实质性的影响。Shafarevich写道:“Weil无疑是对的,他在他的《数论1》俄文版的序言中断言,既然类场论属于数学的基础,每个数学家都应该像熟悉伽罗瓦理论一样熟悉它。”此外,就像之前的伽罗瓦理论一样,阶级场论被认为是非常复杂的,只有专家才能理解……另一方面,对于阶级场域理论来说,有很多本质上不同的解释,因此,即使主题是否相同,也不是立即显而易见的。”Weil的观点被证明是不切实际的:现在甚至一些数论学家也不熟悉CFT的实质。本文回顾了发现CFT新分支及其概括的持久过程。许多这样的发展在早期阶段是复杂的,有些对同时代的人来说是很难或不可能理解的。本文将介绍CFT的三种主要推广及其进一步的扩展,并讨论它们的一些关键基本特征。本文提出了八个基本问题。我们从Kummer理论开始,这是一个纯粹的代数练习,它在算术域上的高度非平凡的算术类似物是由CFT提供的。Kummer理论是CFT的代数前身,包括它的存在性定理。然后讨论了(一维)CFT的基本分裂为特殊CFT (SCFT)和一般CFT (GCFT)。这种分裂极大地影响了数论的许多发展。第3节深入研究了CFT的四个基本部分,包括互易图、存在定理、希尔伯特符号的显式公式及其推广,以及与分支理论的相互作用。第4节简要介绍了使用Milnor k群的更高Kummer理论,即范数剩余同构性质。第5节讨论了CFT的三种推广:朗兰兹对应(LC)、高CFT和安娜贝尔几何。我们注意到,CFT分为SCFT和GCFT,目前在CFT的泛化水平上以某种方式再现:数字域上的LC尚未有任何与GCFT平行的发展,而更高的CFT与GCFT平行,并且没有类似于SCFT的实质性发展。在最后一节中,我们专门讨论全局域上的椭圆曲线,作为一个例子。在这里,我们考虑了两个进一步的发展:望月的泛域Teichmuller理论(IUT),它以anabelian几何和二维adelic分析为中心,以及使用二维CFT结构的几何。我们还考虑了ζ积分的基本作用,它可以统一CFT的不同推广。与LC的情况类似,目前关于数域上椭圆曲线的ζ函数和l函数的特殊值的研究,除了二维曲线分析和几何外,都采用了特殊的结构,不属于一般类型。没有尝试提及CFT中的所有主要结果及其所有概括或所有部分,并且文本不包括所有参考书目。[64][2][3]。
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