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Autor principal:	Wilt, Thomas
Format:	Recurso digital
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Publicat:	Zenodo 2026
Matèries:	Planck's constant golden ratio coupled oscillators energy harvesting solar photovoltaics Shockley-Queisser limit wireless power transfer heat engines electron transport chain dissipative systems continued fractions resonance locking
Accés en línia:	https://doi.org/10.5281/zenodo.19011049
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Planck's relation E = hf — that quantum energy scales with frequency via a universal constant h — has been accepted for 120 years without derivation. This paper shows it is a special case of a universal principle: in any dissipative substrate, energy scales with oscillator frequency via a substrate-specific constant h. Planck's h is the energy quantum of the quantum field substrate specifically. Every dissipative system has its own h. The generalized relation E = hf holds across quantum fields, neural systems, thermal systems, and mechanical systems with the same structural form and substrate-specific constants. From this generalization, combined with the requirement that coupled oscillators minimize inter-stage coupling loss, the golden ratio φ ≈ 1.618 is derived as the thermodynamically optimal frequency ratio between coupled oscillator stages. The derivation uses the theory of continued fractions: φ = [1;1,1,1,...] is the most irrational number — the ratio hardest to approximate by rationals, and therefore the ratio most resistant to resonance locking between coupled stages. Resonance locking dissipates energy. φ-ratio coupling minimizes this loss. This is proven from number theory, not fitted to data. The engineering consequence is a design principle for optimal energy harvesting: any coupled energy conversion system should stage its frequency intervals at φ-scaled ratios to minimize inter-stage coupling loss and maximize transfer efficiency. Applied to solar photovoltaics, this yields a five-junction stack with bandgaps at 0.500, 0.809, 1.309, 2.118, and 3.427 eV — covering the full solar spectrum with φ-ratio spacing — with theoretical efficiency approximately 78%, versus the 33% Shockley-Queisser single-junction limit and the 47% current best multi-junction result. The same principle applies to wireless power transfer, heat engines, thermoelectric generators, antenna arrays, and any other coupled oscillator energy system. Independent confirmation is found in biology: the mitochondrial electron transport chain has evolved redox potential steps with a mean ratio of 1.491, converging on φ = 1.618 through 3 billion years of thermodynamic selection.

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