A Gauge-Invariant Bundle Isomorphism Between Complex Velocity Fields and Symmetric Logarithmic Derivatives

Abstract

We establish a rigorous bundle isomorphism between the complex velocity field ημ = πμ - i uμ, obtained by averaging matter dynamics over stochastic gravitational fluctuations, and the symmetric logarithmic derivative (SLD) operator Lμ of quantum estimation theory. The isomorphism T: (E/) (L) maps gauge-equivalence classes of sections of the pullback bundle E = π2*(T*M) over C × M to SLD operators on the Hilbert space H0 = L2(C, 0), where C is the infinite-dimensional Fr\'echet manifold of matter fields and 0 is a fixed Gaussian measure. We prove that T and the associated quantum Fisher metric are independent of the choice of 0, rendering the construction intrinsic to the physical probability density. The Fisher metric acquires a simple form in terms of the Madelung--Bohm velocities: gμFS = 4m22 [Cov(πμ,π) + Cov(uμ,u)]P. As a consequence, the flat U(1) connection defined by ημ yields a quantized holonomy for non-contractible spacetime loops, predicting topological phases that may be observable in atom interferometry.