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Sheaves of categories with local actions of Hochschild cochains

Part of: (Co)homology theory Categories and geometry Families, fibrations Commutative algebra: Homological methods

Published online by Cambridge University Press:  04 July 2019

Dario Beraldo
Dario Beraldo*
Affiliation:
Institut de mathématiques de Toulouse, Université Paul Sabatier, 118 Route de Narbonne, 31400 Toulouse, France email darioberaldo@gmail.com
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Abstract

The notion of Hochschild cochains induces an assignment from $\mathsf{Aff}$, affine DG schemes, to monoidal DG categories. We show that this assignment extends, under appropriate finiteness conditions, to a functor $\mathbb{H}:\mathsf{Aff}\rightarrow \mathsf{Alg}^{\text{bimod}}(\mathsf{DGCat})$, where the latter denotes the category of monoidal DG categories and bimodules. Any functor $\mathbb{A}:\mathsf{Aff}\rightarrow \mathsf{Alg}^{\text{bimod}}(\mathsf{DGCat})$ gives rise, by taking modules, to a theory of sheaves of categories $\mathsf{ShvCat}^{\mathbb{A}}$. In this paper, we study $\mathsf{ShvCat}^{\mathbb{H}}$. Loosely speaking, this theory categorifies the theory of $\mathfrak{D}$-modules, in the same way as Gaitsgory’s original $\mathsf{ShvCat}$ categorifies the theory of quasi-coherent sheaves. We develop the functoriality of $\mathsf{ShvCat}^{\mathbb{H}}$, its descent properties and the notion of $\mathbb{H}$-affineness. We then prove the $\mathbb{H}$-affineness of algebraic stacks: for ${\mathcal{Y}}$ a stack satisfying some mild conditions, the $\infty$-category $\mathsf{ShvCat}^{\mathbb{H}}({\mathcal{Y}})$ is equivalent to the $\infty$-category of modules for $\mathbb{H}({\mathcal{Y}})$, the monoidal DG category of higher differential operators. The main consequence, for ${\mathcal{Y}}$ quasi-smooth, is the following: if ${\mathcal{C}}$ is a DG category acted on by $\mathbb{H}({\mathcal{Y}})$, then ${\mathcal{C}}$ admits a theory of singular support in $\operatorname{Sing}({\mathcal{Y}})$, where $\operatorname{Sing}({\mathcal{Y}})$ is the space of singularities of ${\mathcal{Y}}$. As an application to the geometric Langlands programme, we indicate how derived Satake yields an action of $\mathbb{H}(\operatorname{LS}_{{\check{G}}})$ on $\mathfrak{D}(\operatorname{Bun}_{G})$, thereby equipping objects of $\mathfrak{D}(\operatorname{Bun}_{G})$ with singular support in $\operatorname{Sing}(\operatorname{LS}_{{\check{G}}})$.

Keywords

Hochschild cochainsquasi-smooth stacksderived algebraic geometryind-coherent sheavessingular supportformal completionsHecke functorsderived Satake

MSC classification

Primary: 14D24: Geometric Langlands program 14F05: Sheaves, derived categories of sheaves and related constructions 13D03: (Co)homology of commutative rings and algebras (e.g., Hochschild, André-Quillen, cyclic, dihedral, etc.) 18F99: None of the above, but in this section
Type
Research Article
Information
Compositio Mathematica , Volume 155 , Issue 8 , August 2019 , pp. 1521 - 1567
Copyright
© The Author 2019 

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Footnotes

Research partially supported by EPSRC programme grant EP/M024830/1 Symmetries and Correspondences, and by grant ERC-2016-ADG-74150.

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