What question did this study set out to answer?

This analysis aims to evaluate the physical consistency and structural features of known physical phenomena across various scales.

May 16, 2026Open Access

The Known Physics Hierarchy: Regime Structure and Coupling Constraints

Key Points

This analysis aims to evaluate the physical consistency and structural features of known physical phenomena across various scales.
Applied logarithmic scale decomposition to 68 physical oscillations from the Planck scale to the cosmic horizon.
Examined frequency-to-scale assignments and coupling spans across 22 log-scaled rungs.
Identified structural transitions within the hierarchy of physical phenomena.
Phenomena divide into two dynamical regimes at atomic scales, with frequencies fitting c/λ within ±0.5 orders below that scale.
Coupling spans form three tiers: local phenomena (66%), quantum-coherent nonlocal phenomena (29%), and extended phenomena (4%).
The 10³ spacing preserves the coupling hierarchy, while 10² leads to inflated global phenomena and empty rungs.

Abstract

"Working preprint. This paper presents a systematic empirical consistency analysis of the known physical hierarchy using a logarithmic scale ladder. " Abstract We apply a logarithmic scale decomposition to 68 known physical oscillations and phenomena spanning from the Planck scale (10⁻³⁵ m) to the cosmic horizon (10²⁸ m). Placing these phenomena on a log-spaced ladder with 22 rungs and a factor of 10³ between adjacent rungs, we ask three questions: (1) Is the frequency-to-scale assignment physically motivated? (2) Do cross-rung coupling spans show structural regularity? (3) Is the 10³ spacing well-chosen, or would 10² or 10⁴ work as well? We find: (1) the catalogue divides into two dynamical regimes at the atomic scale (∼10⁻¹⁰ m) — at smaller scales, characteristic frequencies follow f ≈ c/λ to within ±0. 5 orders; at larger scales, frequencies are set by quantum energy gaps and depart from c/λ by up to 9. 5 orders; (2) coupling spans form a three-tier hierarchy: local phenomena (≤3 rungs, 66%), quantum-coherent nonlocal phenomena (4–6 rungs, 29%), and extended phenomena (≥7 rungs, 4%) ; (3) at 10⁴ spacing, quantum-nonlocal phenomena collapse to the same coupling class as locally-confined oscillations — erasing a physically real distinction; at 10², half the rungs are empty and bulk material phenomena inflate to physically unwarranted global scale. The 10³ spacing is the minimum that preserves the three-tier coupling hierarchy. (4) The layer map reveals a seven-block structural axis with two qualitatively distinct types of regime transition: mechanism shifts, where the dominant frequency-setting principle changes (L8/L9), and organisational transitions, where a new causal hierarchy emerges (L10–L12, the molecular-life bifurcation). Five rungs in the pre-electroweak regime (L2–L6) are structurally empty — a recognised frontier of fundamental physics made explicit by the ladder framework. ORCID: https: //orcid. org/0009-0001-5888-8896 Email: tpuᵢnstitute@outlook. com Funding: No funding was received. You can support this work at https: //buymeacoffee. com/tpuᵢnstitute

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John Carew (Fri,) studied this question.

synapsesocial.com/papers/6a080a71a487c87a6a40c64e https://doi.org/https://doi.org/10.5281/zenodo.20191260

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