Mainstream stellar physics holds that stellar energy originates from a single-point nuclear fusion furnace at the geometric center of a star, yet this classical model contradicts multiple astronomical observational phenomena, including stellar extinction sequences, surface activity distributions and internal energy conduction patterns. This paper first points out a fundamental conceptual error: the phrase "fusion ignition" introduces the notion of "fire", which is a cognitive derivation limited to terrestrial environments. There is no oxygen or combustion in stars, so stellar fusion is not an ignition event but a resonance coupling phenomenon. Furthermore, traditional physics misunderstands the essence of energy: it regards energy as a substance confined inside atomic nuclei that will be released in a violent explosion once external conditions are satisfied, a view rooted in human experience with explosives and nuclear devices rather than the intrinsic topological laws of the universe. Within the four-dimensional topological framework of the PFUSRC system, the interior of atomic nuclei presents an ordered resonance state constrained by topological constants, rather than violent chaos. Energy is released via field coupling instead of explosive eruption. Based on the established 45° triple coaxial biconical global topology theory of the PFUSRC system, this paper constructs a novel stellar structural model: stars possess distributed fusion units in the outer annular layer and a low-temperature hollow core at the center. These distributed fusion units are projected onto stars from the 55 global datum points of the PFUSRC system and follow the spatial distribution rules of prime number nodes. The anchoring primes 2, 3, 5, 7 form the fixed boundary skeleton of stars, while the drift prime number i=11 constitutes the adaptive medium with statistical mobility. This paper adopts the falsification method to disprove the classical central fusion furnace model, explains the non-spherical features of stars from a topological perspective, and establishes a triple closed-loop matter-energy circulation system. Relying on topological tension and the ₁ field, the stability theory of the stellar hollow core is constructed, and a schematic wave dynamics formula is derived to reinterpret helioseismological observation data. By introducing the PFUSRC intrinsic constant pi1 = 12/11, this paper puts forward verifiable quantitative predictions for multiple stellar physical parameters, such as the internal radius ratio of the Sun, helioseismic frequency correction, and the north-south asymmetry phase difference of sunspot cycles. This study also applies the Sevenfold Logic (Bright Sevenfold + Dark Sevenfold) to divide stellar structures into observable Bright Sevenfold domains and implicitly regulated Dark Sevenfold domains. By comparing the topological characteristics of stars and black holes, this paper verifies that the two types of celestial bodies are functional dualities under the unified 45° triple coaxial biconical topology. This research realizes the systematic application of the PFUSRC theoretical system in stellar physics and forms an important empirical part of the Star-Planet Unified Topology Theory.
Zhenmin Wang (Sun,) studied this question.