Finite higher spin transformations from exponentiation
Abstract
We study the exponentiation of elements of the gauge Lie algebras of three-dimensional higher spin theories. Exponentiable elements generate one-parameter groups of finite higher spin symmetries. We show that elements of in a dense set are exponentiable, when pictured in certain representations of , induced from representations of in the complementary series. We also provide a geometric picture of higher spin gauge transformations clarifying the physical origin of these representations. This allows us to construct an infinite-dimensional topological group of finite higher spin symmetries. Interestingly, this construction is possible only for , which are the values for which the higher spin theory is believed to be unitary and for which the Gaberdiel-Gopakumar duality holds. We exponentiate explicitly various commutative subalgebras of . Among those, we identify families of elements of exponentiating to the unit of , generalizing the logarithms of the holonomies of BTZ black hole connections. Our techniques are generalizable to the Lie algebras relevant to higher spin theories in dimensions above three.
Cite
@article{arxiv.1402.4486,
title = {Finite higher spin transformations from exponentiation},
author = {Samuel Monnier},
journal= {arXiv preprint arXiv:1402.4486},
year = {2015}
}
Comments
34 pages. v3: references added. Added a discussion of the Euclidean higher spin symmetry group. Unlike what was claimed in a previous version, the formalism developed here can be applied to the Euclidean case as well