K-Decompositions and 3d Gauge Theories

Abstract

This paper combines several new constructions in mathematics and physics. Mathematically, we study framed flat PGL(K,C)-connections on a large class of 3-manifolds M with boundary. We define a space LK(M) of framed flat connections on the boundary of M that extend to M. Our goal is to understand an open part of LK(M) as a Lagrangian in the symplectic space of framed flat connections on the boundary, and as a K2-Lagrangian, meaning that the K2-avatar of the symplectic form restricts to zero. We construct an open part of LK(M) from data assigned to a hypersimplicial K-decomposition of an ideal triangulation of M, generalizing Thurston's gluing equations in 3d hyperbolic geometry, and combining them with the cluster coordinates for framed flat PGL(K)-connections on surfaces. Using a canonical map from the complex of configurations of decorated flags to the Bloch complex, we prove that any generic component of LK(M) is K2-isotropic if the boundary satisfies some topological constraints (Theorem 4.2). In some cases this implies that LK(M) is K2-Lagrangian. For general M, we extend a classic result of Neumann-Zagier on symplectic properties of PGL(2) gluing equations to reduce the K2-Lagrangian property to a combinatorial claim. Physically, we use the symplectic properties of K-decompositions to construct 3d N=2 superconformal field theories TK[M] corresponding (conjecturally) to the compactification of K M5-branes on M. This extends known constructions for K=2. Just as for K=2, the theories TK[M] are described as IR fixed points of abelian Chern-Simons-matter theories. Changes of triangulation (2-3 moves) lead to abelian mirror symmetries that are all generated by the elementary duality between Nf=1 SQED and the XYZ model. In the large K limit, we find evidence that the degrees of freedom of TK[M] grow cubically in K.