Mainstream cosmology and general relativity have long adopted the mathematical concept of spacetime singularity as a core foundational premise to interpret cosmic genesis, yet no reproducible physical experiment has validated its objective physical existence. Based on the PFUSRC unified topological framework, this paper adopts thin physical sheets with measurable thickness as an intuitive macroscopic experimental carrier, deducing four core physical inferences and establishing an alternative distributed cosmic origin model. Pure mathematical 2D planes with zero thickness do not exist in objective physical reality; perceived planar surfaces are merely cognitive dimensional slices of 3D lattice matter. All deformable, foldable macroscopic material surfaces occupy full 3D spatial volume composed of discrete molecular lattices. Folding deformation essentially represents constrained spatial reconfiguration of 3D material lattices, and its continuous dynamic evolution is defined as the flow variable—an observable macroscopic projection of the "flowing state" ontology proposed in PFUSRC-014. All spatial compression processes demand external energy input and generate irreversible structural damage plus thermal dissipation; zero-cost, zero-entropy compression pathways are physically impossible, which macroscopically falsifies the infinite-density, zero-volume Big Bang singularity model. The initial trigger point of each folding deformation is named Zhao, and cross-scale structural potential trigger points are defined as micro-Zhao. Micro-Zhao are distributed across all spatial coordinates and physical scales, proving that the universe does not rely on a single global singularity as its exclusive genesis boundary. This paper acts as an independent intuitive entry point for the PFUSRC system, rather than a repetition of its formal mathematical proofs. It translates abstract 11-dimensional biconical topology and Logical Origin ontology into repeatable, quantitatively measurable macroscopic experiments, enabling a cognitive transition from abstract mathematical deduction to observable physical facts. All core conclusions can be verified via standard material mechanics testing equipment, with clear experimental protocols provided for cross-checking the framework’s core predictions.
Zhenmin Wang (Thu,) studied this question.