This release presents the complete document set of the Space–Time–Wave (STW, gravitational wave) boundary-closure framework, a speculative geometric programme in which particle sectors are represented as compact boundary states of a common reduced functional. The package comprises the reduced boundary action, the foundational construction, sector studies of neutrinos, charged leptons, quarks, bosons and hadrons, a prediction ledger, an optional parent-CFT/string embedding, and a reader’s guide. The proposed framework begins with compact boundary closure and derives a finite closure-cell structure, an active closure lattice and a universal STW distortion scale. Particle observables are formulated as eigenvalues and interaction tensors obtained by projecting the Hessian and higher variations of the common boundary functional onto sector-specific subspaces. This provides a shared computational architecture for fermion masses, flavour mixing, decay channels, confined states and neutral boundary modes, rather than introducing independent phenomenological rules for each sector. The release reports quantitative or conditional targets including the leptonic CP phase, the neutrino mass scale, charged-lepton and quark spectra, selected hadron and boson masses, a scalar-glueball candidate, and a neutral toroidal dark-sector candidate. It explicitly distinguishes derived results, matched normalizations, regulator-dependent reductions, conditional predictions and unresolved proof obligations. The construction is not claimed as a completed ultraviolet theory or an established alternative to the Standard Model. Its purpose is to expose the full mathematical chain, internal dependencies and falsifiable consequences of the STW hypothesis in a versioned form suitable for critical evaluation and further development.
Vladimir Pavlyuk (Fri,) studied this question.