Einstein Lie groups, geodesic orbit manifolds and regular Lie subgroups

IF 1.2 2区数学 Q1 MATHEMATICS Communications in Contemporary Mathematics Pub Date : 2024-01-24 DOI:10.1142/s0219199723500682

Nikolaos Panagiotis Souris

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Abstract

We study the relation between two special classes of Riemannian Lie groups $G$ with a left-invariant metric $g$ : The Einstein Lie groups, defined by the condition ${Ric}_{g} = c g$ , and the geodesic orbit Lie groups, defined by the property that any geodesic is the integral curve of a Killing vector field. The main results imply that extensive classes of compact simple Einstein Lie groups $(G, g)$ are not geodesic orbit manifolds, thus providing large-scale answers to a relevant question of Nikonorov. Our approach involves studying and characterizing the $G \times K$ -invariant geodesic orbit metrics on Lie groups $G$ for a wide class of subgroups $K$ that we call (weakly) regular. By-products of our work are structural and characterization results that are of independent interest for the classification problem of geodesic orbit manifolds.

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爱因斯坦 Lie 群、大地轨道流形和正则 Lie 子群

我们研究了具有左不变度量 g 的两类特殊黎曼李群 G 之间的关系：由 Ricg=cg 条件定义的爱因斯坦李群和由任何大地线都是基林向量场的积分曲线这一性质定义的大地轨道李群。主要结果意味着大量紧凑简单爱因斯坦李群（G,g）不是大地轨道流形，从而为尼科诺罗夫的一个相关问题提供了大规模答案。我们的方法包括研究和表征我们称之为（弱）正则子群 K 的一大类 Lie 群 G 上的 G×K 不变大地轨道流形。我们工作的副产品是对大地轨道流形分类问题具有独立意义的结构和表征结果。

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来源期刊

Communications in Contemporary Mathematics 数学-数学

CiteScore

2.90

自引率

6.20%

发文量

审稿时长

>12 weeks

期刊介绍： With traditional boundaries between various specialized fields of mathematics becoming less and less visible, Communications in Contemporary Mathematics (CCM) presents the forefront of research in the fields of: Algebra, Analysis, Applied Mathematics, Dynamical Systems, Geometry, Mathematical Physics, Number Theory, Partial Differential Equations and Topology, among others. It provides a forum to stimulate interactions between different areas. Both original research papers and expository articles will be published.

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