English

Minimal coadjoint orbits and symplectic induction

Symplectic Geometry 2007-05-23 v1 Group Theory

Abstract

Let (X,ω)(X,\omega) be an integral symplectic manifold and let (L,)(L,\nabla) be a quantum line bundle, with connection, over XX having ω\omega as curvature. With this data one can define an induced symplectic manifold (X~,ωX~)(\widetilde {X},\omega_{\widetilde {X}}) where dimX~=2+dimXdim \widetilde {X} = 2 + dim X. It is then shown that prequantization on XX becomes classical Poisson bracket on X~\widetilde {X}. We consider the possibility that if XX is the coadjoint orbit of a Lie group KK then X~\widetilde {X} is the coadjoint orbit of some larger Lie group GG. We show that this is the case if GG is a non-compact simple Lie group with a finite center and KK is the maximal compact subgroup of GG. The coadjoint orbit XX arises (Borel-Weil) from the action of KK on \p\p where \g=\k+\p\g= \k +\p is a Cartan decomposition. Using the Kostant-Sekiguchi correspondence and a diffeomorphism result of M. Vergne we establish a symplectic isomorphism (X~,ωX~)(Z,ωZ)(\widetilde {X},\omega_{\widetilde {X}})\cong (Z,\omega_Z) where ZZ is a non-zero minimal "nilpotent" coadjoint orbit of GG. This is applied to show that the split forms of the 5 exceptional Lie groups arise symplectically from the symplectic induction of coadjoint orbits of certain classical groups.

Keywords

Cite

@article{arxiv.math/0312252,
  title  = {Minimal coadjoint orbits and symplectic induction},
  author = {Bertram Kostant},
  journal= {arXiv preprint arXiv:math/0312252},
  year   = {2007}
}

Comments

38 pages, plain tex