Abstract This article formulates the Complete Law of Divalence within the HoloGenesis framework. Divalence is the structural law by which one coherent origin divides into complementary outputs while preserving total frequency, phase, charge, spin, momentum, polarization, curvature, and timing balance. It is proposed as the deeper architecture behind what standard quantum mechanics operationally describes as entanglement. Earlier HoloGenesis treatments introduced Divalence as an alternative to the notion of entanglement, especially in relation to beta decay, weak transformation, and frequency-time emergence (3, 48, 49, 74, 85). HoloGenesis does not deny the predictive success of quantum mechanics, nor does it claim that the mathematical formalism of quantum correlation has already been replaced. The claim is more precise: the term “entanglement” correctly names the observed correlation phenomenon, but it may obscure the underlying structural origin of that correlation. Divalence proposes that correlated outputs do not remain mysteriously connected after separation. They remain constrained because they were born as complementary descendants of one coherence event. This article completes the Divalence doctrine by distinguishing three necessary levels of lawful division. Divalence explains why a coherent origin does not divide into unrelated copies, but into complementary outputs. Orthogonality explains how those outputs stabilize into independent channels without collapsing into redundancy. Noether closure explains why the total ledger remains conserved across the division. Together, these three principles form the HoloGenesis triad of lawful coherent division (34, 75, 76, 81). The article applies this triad to several cases: spontaneous parametric down-conversion, beta decay, charge polarity, neutrality, pair production, annihilation, photon emission, and baryonic reconfiguration. In each case, the same structure appears: one coherence state divides, the outputs differentiate, the channels orthogonalize, and the total ledger is preserved. This connects Divalence to prior HoloGenesis work on weak decay, charge architecture, phasor-tip detection, shell closure, baryonic structures, and the strong force as curvature tension (5, 6, 35, 39, 42, 57, 61, 70, 71, 83, 84). The article also clarifies the relation between Divalence and Bell-type constraints. Divalence is not a naïve local hidden-variable model in which separated particles carry complete prewritten instruction sets. It is a shared-origin, lattice-channel, and measurement-context ontology. It states that correlated outputs inherit a common coherence architecture and that measurement actualizes constrained outcomes within available channels. Therefore, Divalence must be developed as a structural ontology beneath quantum correlation, not as a simplistic return to classical locality. The central formulation is that entanglement is the phenomenon, while Divalence is the architecture. Entanglement describes the observed persistence of correlation. Divalence explains why that persistence is expected: lawful division cannot produce unrelated outputs from one coherence event.
Grégoire Mommaerts (Fri,) studied this question.