Abstract This article proposes a practical test protocol for the Divalence framework within HoloGenesis. Divalence is the structural law by which one coherent origin divides into complementary outputs while preserving a total ledger of frequency, phase, charge, spin, momentum, polarization, curvature, and timing. In previous HoloGenesis work, Divalence was introduced as the architecture behind what standard quantum mechanics operationally describes as entanglement. The present article asks whether this architecture can be connected to existing Bell-test data in a way that gives Divalence practical predictive power. The article does not claim that Divalence has already replaced quantum mechanics, nor that Bell experiments are wrong. On the contrary, the HoloGenesis interpretation accepts Bell violation as a central experimental fact. The key claim is different: Bell violation should not be understood as proof of mysterious post-separation connection. It should be understood as the failure of separable independence after shared-origin division. In HoloGenesis terms, entangled particles are not two unrelated objects later linked across space. They are divalent outputs of one coherence event, actualized through separate measurement channels. This article introduces an important correction to the first Divalence test formulation. Bell degradation should not be described as the particles becoming less divalenced. In HoloGenesis, the particles have already divalenced at origin. The division event is complete at production. Degradation therefore belongs to what happens after Divalence: lattice events, channel disturbances, timing ambiguity, polarization disruption, detector asymmetry, medium effects, accidental coincidences, and measurement-context noise. These later events do not undo the origin-level Divalence. They reduce the readable persistence of the original divalent ledger. For this reason, the article replaces the earlier language of a Divalence coherence factor with the more precise notion of a Divalent Ledger Readability Factor. This factor measures how clearly the original shared-origin ledger remains observable at measurement after post-divalence lattice and channel events. When ledger readability is fully preserved, the ideal quantum correlation is recovered. When ledger readability is destroyed, the Bell correlation disappears from observation, even though the origin-level Divalence has already occurred. The proposed empirical program is straightforward: reanalyze existing Bell-test or spontaneous parametric down-conversion datasets, compute the Bell-correlation strength, extract the observed readability factor, and test whether this factor decreases systematically with controlled degradation variables such as visibility loss, timing-window changes, channel asymmetry, polarization disturbance, detector imbalance, accidental coincidences, source instability, or phase drift. If Divalence is correct as a predictive framework, Bell-correlation strength should degrade in a structured way tied to post-divalence ledger readability rather than randomly. The article therefore defines a modest but meaningful test. Divalence gains predictive advantage only if its readability factor predicts the shape of Bell-correlation degradation better than, or in a physically more unified way than, standard visibility and decoherence parameters. The immediate goal is not to defeat quantum mechanics, but to test whether HoloGenesis can reinterpret Bell correlations through a measurable shared-origin ledger and its post-divalence readability.
Grégoire Mommaerts (Fri,) studied this question.