A better space of generalized connections
Abstract
Given a base manifold M and a Lie group G, we define AHM a space of generalized G-connections on M with the following properties: - The space of smooth connections A∞M = π A∞π is densely embedded in AHM = π AHcc(π); moreover, in contrast with the usual space of generalized connections, the embedding preserves topological sectors. - It is a homogeneous covering space for the standard space of generalized connections of loop quantization AM. - It is a measurable space constructed as an inverse limit of of spaces of connections with a cutoff, much like AM. At each level of the cutoff, a Haar measure, a BF measure and heat kernel measures can be defined. - The topological charge of generalized connections on closed manifolds Q= ∫ Tr(F) in 2d, Q= ∫ Tr(F F) in 4d, etc, is defined. - On a subdivided manifold, it can be calculated in terms of the spaces of generalized connections associated to its pieces. Thus, spaces of boundary connections can be computed from spaces associated to faces. - The soul of our generalized connections is a notion of higher homotopy parallel transport defined for smooth connections. We recover standard generalized connections by forgetting its higher levels. - The kth level of our higher gauge fields is trivial if and only if πk-1 G is trivial. Then AH ≠ A if the gauge group is not simply connected and d ≥ 2. For G=SL(2, C) or G=SU(2) and = 3, however, we get AH = A: Boundary data for loop quantum gravity is consistent with our space of generalized connections, but a path integral for quantum gravity would be sensitive to homotopy data.
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