Intrinsic Heisenberg-type lower bounds on spacelike hypersurfaces in general relativity

Abstract

In quantum theory on curved backgrounds, Heisenberg's uncertainty principle is usually discussed in terms of ensemble variances and flat-space commutators. Here we take a different, preparation-based viewpoint tailored to sharp position measurements on spacelike hypersurfaces in general relativity. A projective localization is modeled as a von Neumann-L\"uders projection onto a geodesic ball B(r) of radius r on a Cauchy slice (,h), with the post-measurement state described by Dirichlet data. Using DeWitt-type momentum operators adapted to an orthonormal frame, we construct a geometric, coordinate-invariant momentum standard deviation σp and show that strict confinement to B(r) enforces an intrinsic kinetic-energy floor. The lower bound is set by the first Dirichlet eigenvalue λ1 of the Laplace-Beltrami operator on the ball, σp λ1, and is manifestly invariant under changes of coordinates and foliation. A variance decomposition separates the contribution of the modulus || from phase-gradient fluctuations and clarifies how the spectral geometry of (,h) controls momentum uncertainty. Assuming only minimal geometric information, weak mean-convexity of the boundary yields a universal, scale-invariant Heisenberg-type product bound, σp r π/2, depending only on the proper radius r.

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