Tensor categories for vertex operator superalgebra extensions
Abstract
Let be a vertex operator algebra with a category of (generalized) modules that has vertex tensor category structure, and thus braided tensor category structure, and let be a vertex operator (super)algebra extension of . We employ tensor categories to study untwisted (also called local) -modules in , using results of Huang-Kirillov-Lepowsky showing that is a (super)algebra object in and that generalized -modules in correspond exactly to local modules for the corresponding (super)algebra object. Both categories, of local modules for a -algebra and (under suitable conditions) of generalized -modules, have natural braided monoidal category structure, given in the first case by Pareigis and Kirillov-Ostrik and in the second case by Huang-Lepowsky-Zhang. Our main result is that the Huang-Kirillov-Lepowsky isomorphism of categories between local (super)algebra modules and extended vertex operator (super)algebra modules is also an isomorphism of braided monoidal (super)categories. Using this result, we show that induction from a suitable subcategory of -modules to -modules is a vertex tensor functor. We give two applications. First, we derive Verlinde formulae for regular vertex operator superalgebras and regular -graded vertex operator algebras by realizing them as (super)algebra objects in the vertex tensor categories of their even and -graded components, respectively. Second, we analyze parafermionic cosets where is a positive definite even lattice and is regular. If the category of either -modules or -modules is understood, then our results classify all inequivalent simple modules for the other algebra and determine their fusion rules and modular character transformations. We illustrate both directions with several examples.
Cite
@article{arxiv.1705.05017,
title = {Tensor categories for vertex operator superalgebra extensions},
author = {Thomas Creutzig and Shashank Kanade and Robert McRae},
journal= {arXiv preprint arXiv:1705.05017},
year = {2024}
}
Comments
133 pages, final version to appear in Mem. Amer. Math. Soc., incorporating referee suggestions; in this version, many lengthy tensor category arguments in Section 2 have been replaced with graphical calculus, and more details and motivation have been added in Section 4; references and discussion related to recent progress have also been added