Void-Pair Conservation as the Physical Mechanism of Quantum Entanglement and Bell Correlations

We propose that quantum entanglement is the physical manifestation of void-pair conservation in a quantized vacuum foam. The conservation law B(x) + V(x') = D requires that every vacuum displacement event D creates exactly one bubble B at position x and one complementary void V at position x'. Entangled particles are two addresses of one displacement event — not two correlated objects but two endpoints of one physical thing. This escapes Bell's theorem without local hidden variables: Bell's factorization assumption requires the correlation function to be writable as a product of local functions, but D is inherently non-local and cannot be so factored. The antipodal symmetry of the void-pair uniquely selects the quantum singlet state, producing the experimentally confirmed correlation E(a,b) = -cos(theta_ab). We verify numerically that the model reproduces the full quantum mechanical CHSH violation S = 2*sqrt(2). We propose a testable prediction for three-particle connected foam topologies that differs from the standard GHZ prediction.

UFFT Paper #2. Part of the Unified Foam Field Theory (B + V = D). Zero free parameters.
GitHub: https://github.com/WebEnvy/UnifiedFoamFieldTheory