A general mirror equivalence theorem for coset vertex operator algebras

Abstract

We prove a general mirror duality theorem for a subalgebra U of a simple conformal vertex algebra A and its commutant V=ComA(U). Specifically, we assume that Ai∈ I Ui Vi as a U V-module, where the U-modules Ui are simple and distinct and are objects of a semisimple braided ribbon category of U-modules, and the V-modules Vi are semisimple and contained in a (not necessarily rigid) braided tensor category of V-modules. We also assume U=ComA(V). Under these conditions, we construct a braid-reversed tensor equivalence τ: UA→VA, where UA is the semisimple category of U-modules with simple objects Ui, i∈ I, and VA is the category of V-modules whose objects are finite direct sums of the Vi. In particular, the V-modules Vi are simple and distinct, and VA is a rigid tensor category. As an application, we find a rigid semisimple tensor subcategory of modules for the Virasoro algebra at central charge 13+6p+6p-1, p∈Z≥ 2, which is braided tensor equivalent to an abelian 3-cocycle twist of the category of finite-dimensional sl2-modules. Consequently, the Virasoro vertex operator algebra at central charge 13+6p+6p-1 is the PSL2(C)-fixed-point subalgebra of a simple conformal vertex algebra W(-p), analogous to the realization of the Virasoro vertex operator algebra at central charge 13-6p-6p-1 as the PSL2(C)-fixed-point subalgebra of the triplet algebra W(p).