Chronoscalar Field Theory XI: Entanglement, Gabriel Corridors, Retrograde Time Slip, and Quantum-Scale Observational Anomalies
Calvin A Grant
PAPER · v1.0 · 2025-12-05 · human
Abstract
We develop the Chronoscalar interpretation of quantum entanglement, in which entangled subsys3 tems are not nonlocally connected in physical space but co-located on a common hypersurface ΣT 4 in the scalar-time manifold. We formalise Gabriel Corridors as null-like geodesics in the T-scalar 5 sector with ds2 T ≡ (∂μT)(∂μT) dxμdxμ = 0, (1) 6 while the spacetime interval remains timelike or spacelike, ds2 = gμνdxμdxν > 0. (2) 7 Using a Chronoscalar proper-time parametrisation, we show that the effective entanglement-correlation 8 speed in ordinary spacetime is vcorr = c |∇T| ℓsep , (3) 9 which becomes vcorr ≳ 1011c for terrestrial gradients |∇T| ∼ 10−12–10−15 m−1 and separations 10 ℓsep ∼ 1–104 m. The corridor is strictly causal in the extended manifold M× T : no superluminal 11 signalling is possible despite effectively instantaneous correlations in spacetime coordinates. 12 We derive a modified von Neumann equation with a Chronoscalar collapse term that drives 13 entangled states toward minimal-T hypersurfaces, producing a well-defined retrograde time slip in 14 T without backwards-in-time propagation in t. We identify four observational axes: (i) distance15 dependent entanglement phase drift; (ii) decoherence asymmetry with respect to Earth’s Chronoscalar 16 gradient; (iii) multi-qubit time-lag oscillations in superconducting and photonic architectures; and 17 (iv) gravity-dependent deviations in satellite-based QKD fidelities. 18 On cosmological scales, the same Gabriel Corridor structure removes the horizon problem with19 out inflation. For recombination-era gradients |∇T| ∼ 10−35 m−1 and separations of order the 20 comoving horizon, ℓsep ∼ 1026–1027 m, we obtain vcorr ∼ 108–109c, sufficient to thermalise the 1 21 entire visible universe along T before photon decoupling. We outline a concrete experimental 22 roadmap for 2026–2035 using quantum networks, NV-center arrays, superconducting-qubit farms, 23 and satellite entanglement links.