We present a preliminary computational study proposing that diatomic nitrogen (N₂) retains a measurable spectroscopic memory of its formation from a high-symmetry polynitrogen precursor (N₁₂). This memory, quantified by a hysteresis coefficient η = 8.28×10⁻⁶, manifests as a persistent redshift in the Raman active stretching frequency of a refined species N₂* relative to standard N₂, across all finite pressures. A closed-form pressure-dependent model for the frequency gap and a Unified Toughness Factor are derived and numerically validated. The CL5D five-stage regulatory framework maps this behaviour onto five processing dimensions, yielding a convergence score that quantifies the survival of the 5D memory state under external pressure. A Singularity Exclusion Zone is formally defined, showing that the system asymptotically approaches but never reaches complete memory erasure. Potential applications in high-pressure gas storage and precision Raman spectroscopy are discussed. The central prediction — ν*(1000 atm) = 2395.639 cm⁻¹ — is falsifiable by existing high-pressure Raman technology.
Mrinmoy Chakraborty (Mon,) studied this question.