Tensor category of Z2-orbifold of Heisenberg vertex operator algebra and its applications

Abstract

In this paper, we prove the category of finite length modules for the Z2-orbifold M(1)+ of the Heisenberg vertex operator algebra whose simple composition factors are M(1) or M(1,λ) for λ ∈ C× is a vertex and braided tensor category. Our strategy is to show these simple composition factors are C1-cofinite and the category of finite length M(1)+-modules is exactly the category of grading-restricted C1-cofinite modules. We also determine the fusion product decompositions of simple objects and prove the rigidity of this category. As an application of the tensor category structure of M(1)+-modules, we prove the category C-1(sp(2n)) of grading-restricted generalized modules for the simple affine vertex algebra L-1(sp(2n)) is semisimple. For this, we first prove M(1)+ and simple affine vertex algebra L-12(sp(2n)) form a commutant pair in the simple minimal W-algebra W-1min(sp(2n)) for n ≥ 2 and determine W-1min(sp(2n)) as well as its irreducible modules obtained from quantum Hamilton reduction as decompositions of M(1)+ L-12(sp(2n))-modules, then we show all the highest weight modules for L-1(sp(2n)) in C-1(sp(2n)) are irreducible via the quantum Hamilton reduction. We also prove a Schur-Weyl duality between L-1(sp(2n)) and M(1)+ by showing they form a commutant pair in the Z2-orbifold of the rank n βγ system, and then establish a braided reversed equivalence between the category C-1(sp(2n)) and the full subcategory of C1-cofinite M(1)+-modules consisting of direct sums of irreducible modules M(1) and M(1, s-2n) for s ∈ Z≥ 0.