Equivariant Functors and Sheaves
Abstract
In this thesis we study two main topics which culminate in a proof that four distinct definitions of the equivariant derived category of a smooth algebraic group acting on a variety are in fact equivalent. In the first part of this thesis we introduce and study equivariant categories on a quasi-projective variety . These are a generalization of the equivariant derived category of Lusztig and are indexed by certain pseudofunctors that take values in the 2-category of categories. This 2-categorical generalization allow us to prove rigorously and carefully when such categories are additive, monoidal, triangulated, admit -structures, among and more. We also define equivariant functors and natural transformations before using these to prove how to lift adjoints to the equivariant setting. We also give a careful foundation of how to manipulate -structures on these equivariant categories for future use and with an eye towards future applications. In the final part of this thesis we prove a four-way equivalence between the different formulations of the equivariant derived category of -adic sheaves on a quasi-projective variety . We show that the equivariant derived category of Lusztig is equivalent to the equivariant derived category of Bernstein-Lunts and the simplicial equivariant derived category. We then show that these equivariant derived categories are equivalent to the derived -adic category of Behrend on the algebraic stack . We also provide an isomorphism of the simplicial equivariant derived category on the variety with the simplicial equivariant derived category on the simplicial presentation of , as well as prove explicit equivalences between the categories of equivariant -adic sheaves, local systems, and perverse sheaves with the classical incarnations of such categories of equivariant sheaves.
Cite
@article{arxiv.2110.01130,
title = {Equivariant Functors and Sheaves},
author = {Geoff Vooys},
journal= {arXiv preprint arXiv:2110.01130},
year = {2023}
}
Comments
455 Pages. Ver 3: Fixed the definition of etale locally trivializable quotient map as well as the proofs that used this definition