English

Bott-Samelson varieties and Poisson Ore extensions

Differential Geometry 2017-11-03 v2 Representation Theory

Abstract

Let GG be a connected complex semi-simple Lie group, and let ZuZ_{{\bf u}} be an nn-dimensional Bott-Samelson variety of GG, where u{\bf u} is any sequence of simple reflections in the Weyl group of GG. We study the Poisson structure πn\pi_n on ZuZ_{\bf u} defined by a standard multiplicative Poisson structure πst\pi_{\rm st} on GG. We explicitly express πn\pi_n on each of the 2n2^n affine coordinate charts, one for every subexpression of u{\bf u}, in terms of the root strings and the structure constants of the Lie algebra of GG. We show that the restriction of πn\pi_n to each affine coordinate chart gives rise to a Poisson structure on the polynomial algebra C[z1,,zn]{\mathbb{C}}[z_1, \ldots, z_n] which is an {\it iterated Poisson Ore extension} of C\mathbb{C} compatible with a rational action by a maximal torus of GG. For canonically chosen πst\pi_{\rm st}, we show that the induced Poisson structure on C[z1,,zn]{\mathbb{C}}[z_1, \ldots, z_n] for every affine coordinate chart is in fact defined over Z{\mathbb Z}, thus giving rise to an iterated Poisson Ore extension of any field k{\bf k} of arbitrary characteristic. The special case of πn\pi_n on the affine chart corresponding to the full subexpression of u{\bf u} yields an explicit formula for the standard Poisson structures on {\it generalized Bruhat cells} in Bott-Samelson coordinates. The paper establishes the foundation on generalized Bruhat cells and sets up the stage for their applications, some of which are discussed in the Introduction of the paper.

Keywords

Cite

@article{arxiv.1601.00047,
  title  = {Bott-Samelson varieties and Poisson Ore extensions},
  author = {Balazs Elek and Jiang-Hua Lu},
  journal= {arXiv preprint arXiv:1601.00047},
  year   = {2017}
}

Comments

Title changes; Introduction expanded; Some typos corrected

R2 v1 2026-06-22T12:21:19.105Z