The three-dimensional humanoid projection image preserved on the Shroud of Turin has long presented an explanatory blind spot across the intersecting fields of physics, chemistry, and archaeology. Neither classical theories nor modern cutting-edge paradigms can fully match its unique physical characteristics. This paper, grounded in the PFUSRC 11-dimensional triple coaxial bicone topological unification system, constructs a novel topological field imprint physical model and systematically elucidates the formation mechanism of the Shroud’s anomalous image. By layering and deconstructing the material residue characteristics on the fabric surface, and comparing the thermodynamic evolution laws of conventional material traces-bloodstains, pollen, and biological fingerprints-this study demonstrates that the humanoid image does not follow the classical physical laws of material decay, permeation, or adhesion. Through exhaustive exclusion of all known imaging mechanisms-including painting, dyeing, optical imaging, broadband high-energy radiation, natural staining, microbial chromogenesis, and mineral crystal precipitation-this paper identifies the image as a steady-state structured imprint formed by high-dimensional topological fields acting on low-dimensional material surfaces. Based on the core PFUSRC framework components-the 45° triple coaxial bicone steady-state topological geometry, the binary coupling architecture of Noetic and Affective primordia, and the global field coupling mechanism-this work fully derives the core physical logic of three-dimensional topological information dimensionality reduction projection, material-free adhesion, and long-term steady-state locking. This paper further defines the emergent field-readout technical paradigm, distinct from traditional optical intensity detection logic, and supplements quantitative observation thresholds with clear falsifiability criteria, providing a feasible theoretical pathway and observational standards for experimental verification of topological field imprints. This research breaks through the cognitive boundaries of classical material imaging and offers a novel ontological framework and technical support for unconventional surface information imprints, high-dimensional topological dimensionality reduction representation, and global field coupling applications.
Zhenmin Wang (Sat,) studied this question.
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