Infinite dimensional Lie theory and representation theory

无限维李理论和表示论

• 批准号: 355464-2013
• 负责人: Salmasian, Hadi
• 金额: $ 1.09万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=572581
• 关键词: Infinite; dimensional; Lie; theory; representation

More than a hundred years ago, the Norwegian mathematician Sophus Lie introduced the basic ideas of Lie theory as a means to study problems in the area of differential equations. From then on, Lie theory has emerged to an integral part of contemporary mathematics which interacts with several other areas, such as differential geometry, algebraic geometry, harmonic analysis, mathematical physics, dynamical systems, and number theory, to name a few. The fundamental objects of Lie theory are continuous transformation groups which are called Lie groups, and certain algebraic structures associated to Lie groups which are called Lie algebras. In many branches of physics and mathematics, Lie groups and Lie algebras can be used to describe and better understand continuous symmetries. Generally speaking, what links a Lie group to symmetries of a mathematical or a physical system is an algebraic structure which is called the representation of the Lie group (or its associated Lie algebra). For example, in modern physics, representations of the Lorentz group have been used to understand various properties of elementary particles. The existing interaction between Lie theory and physics reveals yet another aspect of the subject: that the infinite dimensional Lie groups and Lie algebras are as important as the finite dimensional ones. Motivated by the advent of supersymmetry as a theory in particle physics, in the 1970's mathematicians as well as physicists were drawn to study the structure and representations of graded analogues of Lie groups and Lie algebras which are nowadays called Lie supergroups and Lie superalgebras. The idea that underlies these graded concepts is to allow both commuting and anti-commuting coordinates. The introduction of Lie supergroups and Lie superalgebras has led to a whole new domain of active mathematical research. The goal of this proposal is to study the structure theory and representation theory of Lie algebras/Lie groups and Lie superalgebras/Lie supergroups.

一百多年前，挪威数学家 Sophus Lie 引入了李理论的基本思想，作为研究微分方程领域问题的手段。从那时起，李理论就成为当代数学不可或缺的一部分，它与微分几何、代数几何、调和分析、数学物理、动力系统和数论等其他领域相互作用。李理论的基本对象是连续变换群（称为李群）以及与李群相关的某些代数结构（称为李代数）。在物理和数学的许多分支中，李群和李代数可用于描述和更好地理解连续对称性。一般来说，将李群与数学或物理系统的对称性联系起来的是一种代数结构，称为李群的表示（或其相关的李代数）。例如，在现代物理学中，洛伦兹群的表示已被用来理解基本粒子的各种性质。李理论和物理学之间现有的相互作用揭示了该主题的另一个方面：无限维李群和李代数与有限维李群和李代数一样重要。受超对称性作为粒子物理学理论出现的推动，在 1970 年代，数学家和物理学家被吸引去研究李群和李代数的分级类似物的结构和表示，现在被称为李超群和李超代数。这些分级概念背后的想法是允许通勤和反通勤坐标。李超群和李超代数的引入导致了活跃的数学研究的全新领域。该提案的目标是研究李代数/李群和李超代数/李超群的结构理论和表示论。