English

Hessenberg varieties and Poisson slices

Symplectic Geometry 2020-08-18 v2 Algebraic Geometry Representation Theory

Abstract

This work pursues a circle of Lie-theoretic ideas involving Hessenberg varieties, Poisson geometry, and wonderful compactifications. In more detail, one may associate a symplectic Hamiltonian GG-variety μ:G×Sg\mu:G\times\mathcal{S}\longrightarrow\mathfrak{g} to each complex semisimple Lie algebra g\mathfrak{g} with adjoint group GG and fixed Kostant section Sg\mathcal{S}\subseteq\mathfrak{g}. This variety is one of Bielawski's hyperk\"ahler slices, and it is central to Moore and Tachikawa's work on topological quantum field theories. It also bears a close relation to two log symplectic Hamiltonian GG-varieties μS:G×Sg\overline{\mu}_{\mathcal{S}}:\overline{G\times\mathcal{S}}\longrightarrow\mathfrak{g} and ν:Hessg\nu:\mathrm{Hess}\longrightarrow\mathfrak{g}. The former is a Poisson transversal in the log cotangent bundle of the wonderful compactification G\overline{G}, while the latter is the standard family of Hessenberg varieties. Each of μ\overline{\mu} and ν\nu is known to be a fibrewise compactification of μ\mu. We exploit the theory of Poisson slices to relate the fibrewise compactifications mentioned above. Our main result is a canonical GG-equivariant bimeromorphism HessG×S\mathrm{Hess}\cong\overline{G\times\mathcal{S}} of varieties over g\mathfrak{g}. This bimeromorphism is shown to be a Hamiltonian GG-variety isomorphism in codimension one, and to be compatible with a Poisson isomorphism obtained by B\u{a}libanu. We also show our bimeromorphism to be a biholomorphism if g=sl2\mathfrak{g}=\mathfrak{sl}_2, and we conjecture that this is the case for arbitrary g\mathfrak{g}. We conclude by discussing the implications of our conjecture for Hessenberg varieties.

Keywords

Cite

@article{arxiv.2005.00874,
  title  = {Hessenberg varieties and Poisson slices},
  author = {Peter Crooks and Markus Röser},
  journal= {arXiv preprint arXiv:2005.00874},
  year   = {2020}
}

Comments

31 pages

R2 v1 2026-06-23T15:15:48.732Z