Topological Quantization of Complex Velocity in Stochastic Spacetimes

Abstract

We establish a rigorous geometric framework for quantum fields on a stochastic gravitational background. Starting from a master partition function that averages over metric fluctuations, we define a matter amplitude K, whose logarithmic derivative yields a complex velocity field ημ = πμ - i uμ. This object, originating in Nelson's stochastic mechanics, is a section of the pullback bundle E = π2*(T*M) over the product of configuration space C and spacetime M. We prove that ημ defines a flat U(1) connection with K as its horizontal section, and via a bundle isomorphism it maps to the symmetric logarithmic derivative of quantum estimation theory. The coupled dynamics collapse into Lηη = d(|η|2). We resolve the tension between flatness and multi-valuedness: although the connection is flat, the potential can be multi-valued from topological terms or branch cuts. The total phase satisfies mγ ημ dxμ = 2π n + φtop. We demonstrate this in a toy model: a scalar field on a conical spacetime with deficit angle α, computing the matter amplitude in the Gaussian approximation, deriving the complex velocity, and calculating its holonomy. The resulting topological offset receives a quantized stochastic correction depending on the variance of metric fluctuations, providing an experimental signature for atom interferometry. This framework geometrizes quantum mechanics without hidden variables: stochasticity imprints spacetime fluctuations on matter, preserving the wave function's probabilistic nature while giving a geometric origin for the Born rule.

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