We propose a Multi-Layer Cosmology in which the observable universe is realized as a nonlinear projection of a higher-dimensional Super-Layer supporting a fundamen- tal phase field Φ. In this framework, the familiar four-dimensional spacetime — the Physical-Layer — is not fundamental but emerges as an effective “shadow” of a deeper, higher-dimensional structure. Gravity, time, and the dark sector (dark matter and dark energy) arise as emergent phenomena tied to the geometry, phase structure, and dynamics of the Super-Layer and the projection map connecting the two layers.We construct a minimal formalism by introducing: (i) a higher-dimensional manifold S equipped with a metric GAB and a complex phase field Φ; (ii) an emergent Physical- Layer spacetime P with metric gµν ; and (iii) a nonlinear projection map π : S → P which defines the effective metric, matter content, and dark components observed in P . The Einstein–Hilbert action and the standard ΛCDM model appear as low- energy, coarse-grained limits of the more fundamental Super-Layer dynamics. Localized excitations of Φ project to dark matter-like components, while a nearly homogeneous background of the Super-Layer phase field yields an effective cosmological constant or dynamical dark energy. We derive a schematic effective action for the Physical-Layer, recover General Rela- tivity in an appropriate limit, and show how modified Friedmann equations can encode dark matter and dark energy as projection-induced terms. We then discuss conceptual implications for the origin of time, the arrow of time, and the interpretation of the Big Bang as a projected phase transition, rather than a literal singular beginning of all existence. Finally, we outline potential observational signatures — including devia- tions from ΛCDM in the growth of structure, the CMB, and large-scale gravity — and summarize how future surveys may test whether our universe is indeed a Multi-Layer projection of a deeper Super-Layer reality.
Park Ji-won (Fri,) studied this question.