This paper is archived as a speculative research work. This paper rewrites the EAS scalar-field axiom system around point-to-associate second-order ordering (SOO). The earlier point-to-self comparison Phiₑll - Phi₄₋₋-₁ is demoted to the identity-association special case. The primary scalar-field comparison is instead PiₑllA = Phiₑll - Aₓ₇₄ₓ₀䂰₋₋ Phi₄₋₋-₁, where Aₓ₇₄ₓ₀䂰₋₋ is the active association operator selected by the global rank-3 phase thetaₑll in 0, 1, 2. This makes rank-3 association records active in scalar-value ordering without treating them as spatial directions, geometric tensor components, or propagating channels. The paper separates three notions that must not be conflated. Rank-3 phase is global, discrete, and presentation-level. Pointwise handedness, where defined, is local cyclic orientation/facing relative to the global phase order. Continuous phase appears only later, as report-wave phase in stable recurrent wave sectors. Thus, the phase relevant to Noether-facing structure is not the EAS rank-3 phase and is not imported from QFT. It arises from stable recurrent pattern waves generated by the association-indexed cyclic return map F₂ₘ₂, ₀ = F₂, ₀ o F₁, ₀ o F₀, ₀. A recurrent pattern wave is defined as a stable elliptic block of this cyclic return map. On such a block, the return action has rotation form, or equivalently complex eigenvalues e^± i omegaⱼ. This permits a report-wave coordinate zⱼ = Aⱼ e^i alphaⱼ, where alphaⱼ is a continuous report-level phase. Continuous symmetries of stable wave-coordinate sectors then supply the scalar-field location of Noether-facing conservation. In particular, when Z₍+₁ = Dₒmega Zₙ and a continuous wave-sector generator Xi commutes with Dₒmega, the report JXi^wave (n) = is conserved under full cyclic return. This recurrent-wave construction is valid, but it is not a complete whole-field diagnostic. It identifies one major report-level structure generated by point-to-associate SOO: stable cyclic-return wave sectors carrying continuous report phase and Noether-facing conserved reports. It does not claim that recurrent pattern waves provide a complete account of whole-field scalar-field report structure. In particular, whole-field phase-complete relational closure, branch-resolved regional report algebras, report-state functionals, and nonfactorization diagnostics belong to a downstream diagnostic layer. These objects are report-level and non-certifying: they do not define SOO, create branch classes, certify recurrence, or alter scalar-field ontology. The result is conditional and report-level. It does not derive QFT, Maxwell's equations, the Dirac equation, canonical anticommutation relations, empirical charge, QFT vacuum entanglement, or a primitive electromagnetic field. It identifies the scalar-field mathematical location where recurrent pattern waves, continuous report phases, Noether-facing conserved reports, and later gauge-facing comparison structures can arise without making rank-3 phase local and without importing spacetime or QFT phase into scalar-field ontology. The paper also records two path-capability admissibilities needed by later photon-like and Lorentz-facing report language. Universal photonic path capacity says that every scalar point belongs to at least one locally admissible rank-3 path patch capable of supporting a photon-like successor record. Undefined-point path seeding says that, when a scalar point with undefined associations first receives an association in an ordered scalar-field presentation, that first assigned association is path-facing for purposes of relational-path capacity. These admissibilities supply channel-readiness and first-association slot-role asymmetry only. They do not certify photon-like activation, do not introduce photon objects, and do not weaken the separate loaded-record certification required for photon-like reports. The next formal layer is therefore not a replacement for point-to-associate SOO, but a branch-resolved report-algebra diagnostic layer built downstream from it.
Michael Labhard (Thu,) studied this question.