Grothendieck-Springer resolutions and TQFTs
Abstract
The Moore-Tachikawa conjecture is that each connected complex semisimple group G determines a two-dimensional TQFT in a category of Hamiltonian symplectic varieties. While it would be worthwhile to prove this conjecture outright, our objectives are drastically different. We instead view the Moore--Tachikawa conjecture as a first step in systematically assigning new TQFTs to purely Lie-theoretic data. At the same time, one should expect these new TQFTs to bear a close relation to those conjectured by Moore and Tachikawa. Our manuscript aims to integrate these two points of view. Let g be the Lie algebra of G. Consider a conjugacy class C of parabolic subalgebras of g. This class determines partial Grothendieck--Springer resolutions μC:gCg*=g and C:GC G. We construct a canonical symplectic groupoid (T*G)C\\[-9pt] gC and quasi-symplectic groupoid D(G)C\\[-9pt] GC. By considering a Kostant slice Kos⊂eqg and Steinberg slice Ste⊂eq G, we prove that the pairs (((T*G)C)reg\\[-9pt] (gC)reg,μC-1(Kos)) and ((D(G)C)reg\\[-9pt] (GC)reg,C-1(Ste)) determine new and explicit TQFTs in a 1-shifted Weinstein symplectic category. We then show that certain symplectic varieties arising from our new TQFTs have canonical Lagrangian relations to the open Moore-Tachikawa varieties.
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