This paper explores the thermodynamic and temporal implications of the Quantum Diffusion (DQ) Framework, proposing a theoretical mechanism for the direct observation of past events without violating classical causality. By eliminating quantum randomness and establishing a strictly deterministic universe grounded in 12-dimensional topology, the DQ Framework postulates that physical information is indestructible. Two mechanisms for the recovery of historical data are introduced: the inverse computation of the "Topological Echo" (residual gauge friction in the subspace) and the geometric manipulation of ancient light using a "Diffusivity Mirror 𝐷 → 0." The concept of the DQ Chronoscope transforms time into a mathematically reversible thermodynamic gradient, redefining history and archaeology as disciplines of exact physics.
VARCO et al. (Thu,) studied this question.