The Moore-Tachikawa conjecture via shifted symplectic geometry

Abstract

We use shifted symplectic geometry to construct the Moore-Tachikawa topological quantum field theories (TQFTs) in a category of Hamiltonian schemes. Our new and overarching insight is an algebraic explanation for the existence of these TQFTs, i.e. that their structure comes naturally from three ingredients: Morita equivalence, as well as multiplication and identity bisections in abelian symplectic groupoids. Using this insight, we generalize the Moore-Tachikawa TQFTs in two directions. The first generalization concerns a 1-shifted version of the Weinstein symplectic category WS1. Each abelianizable quasi-symplectic groupoid G is shown to determine a canonical 2-dimensional TQFT ηG:Cob2WS1. We recover the open Moore-Tachikawa TQFT and its multiplicative counterpart as special cases. Our second generalization is an affinization process for TQFTs. We first enlarge Moore and Tachikawa's category MT of holomorphic symplectic varieties with Hamiltonian actions to AMT, a category of affine Poisson schemes with Hamiltonian actions of affine symplectic groupoids. We then show that if G X is an affine symplectic groupoid that is abelianizable when restricted to an open subset U ⊂eq X statisfying Hartogs' theorem, then G determines a TQFT ηG : Cob2 AMT. In more detail, we first devise an affinization process sending 1-shifted Lagrangian correspondences in WS1 to Hamiltonian Poisson schemes in AMT. The TQFT is obtained by composing this affinization process with the TQFT ηG|U : Cob2 WS1 of the previous paragraph. Our results are also shown to yield new TQFTs outside of the Moore-Tachikawa setting.