Cosimplicial monoids and deformation theory of tensor categories

IF 0.7 2区数学 Q2 MATHEMATICS

Journal of Noncommutative Geometry Pub Date : 2020-03-29 DOI:10.4171/jncg/512

M. Batanin, A. Davydov

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引用次数: 4

Abstract

We introduce a notion of $n$-commutativity ($0\le n\le \infty$) for cosimplicial monoids in a symmetric monoidal category ${\bf V}$, where $n=0$ corresponds to just cosimplicial monoids in ${\bf V,}$ while $n=\infty$ corresponds to commutative cosimplicial monoids. If ${\bf V}$ has a monoidal model structure we show (under some mild technical conditions) that the total object of an $n$-cosimplicial monoid has a natural $E_{n+1}$-algebra structure. Our main applications are to the deformation theory of tensor categories and tensor functors. We show that the deformation complex of a tensor functor is a total complex of a $1$-commutative cosimplicial monoid and, hence, has an $E_2$-algebra structure similar to the $E_2$-structure on Hochschild complex of an associative algebra provided by Deligne's conjecture. We further demonstrate that the deformation complex of a tensor category is the total complex of a $2$-commutative cosimplicial monoid and, therefore, is naturally an $E_3$-algebra. We make these structures very explicit through a language of Delannoy paths and their noncommutative liftings. We investigate how these structures manifest themselves in concrete examples.

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张量范畴的同素单胚与变形理论

我们引入了对称幺群范畴$｛\bf V｝$中的共单半群的$n$-交换性（$0\le n\le \infty$）的概念，其中$n=0$仅对应于$｛bf V，｝$的共单半群，而$n=\infty$$对应于交换的共单双群。如果$｛\bf V｝$具有单oid模型结构，我们（在一些温和的技术条件下）证明了$n$-共简单单oid的总对象具有自然的$E_｛n+1｝$-代数结构。我们的主要应用是张量范畴和张量函子的变形理论。我们证明了张量函子的变形复形是$1$-交换共单半群的全复形，因此，它具有$E_2$-代数结构，类似于Deligne猜想提供的结合代数Hochschild复形上的$E_2$结构。我们进一步证明了张量范畴的变形复形是一个$2$-交换共单半群的总复形，因此，它自然是一个$E_3$-代数。我们通过Delannoy路径及其非交换提升的语言使这些结构非常明确。我们研究了这些结构是如何在具体例子中表现出来的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Noncommutative Geometry 数学-数学

CiteScore

1.60

自引率

11.10%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Noncommutative Geometry covers the noncommutative world in all its aspects. It is devoted to publication of research articles which represent major advances in the area of noncommutative geometry and its applications to other fields of mathematics and theoretical physics. Topics covered include in particular: Hochschild and cyclic cohomology K-theory and index theory Measure theory and topology of noncommutative spaces, operator algebras Spectral geometry of noncommutative spaces Noncommutative algebraic geometry Hopf algebras and quantum groups Foliations, groupoids, stacks, gerbes Deformations and quantization Noncommutative spaces in number theory and arithmetic geometry Noncommutative geometry in physics: QFT, renormalization, gauge theory, string theory, gravity, mirror symmetry, solid state physics, statistical mechanics.