Entropy-Driven Emergent Suppression: From LIGO to the Planck Scale

We demonstrate that high-energy “fade‑outs” across disparate physical systems—from photon shot‑noise in LIGO to quantum‑gravity corrections in the early universe—obey a single, entropy‑driven suppression principle. By independently fitting the crossover scale E0 in laboratory, astrophysical, and Planck‑scale contexts, and by invertingE0 = √(ħ c s)to compute each system’s mode entropy density s, we show quantitative agreement over ∼19 orders of magnitude in E0. This unifies four rigorous theoretical derivations (analytic continuation, field‑theoretic propagators, Jaynes’ max‑entropy/QFI, geometric/holographic) under one emergent framework, and rules out competing power laws (e.g. 1/E, 1/E^3, 1/E^4) at high confidence.