Vibration is the most fundamental form of response to external disturbances. From atomic lattices to macroscopic mechanical resonators, from electromagnetic waves to quantum fields, vibrational phenomena exhibit a universal structure: periodic exchange between constrained potential energy and free kinetic energy. This paper develops a unified interpretation within Energy-Efficiency Theory (EET). We show that Yang's Energy-Efficiency Cycle (YEC) — disturbance → response → stabilization → constraint → transition — is exactly the dynamical grammar of a harmonic oscillator. The total input power is partitioned as Ėᵢn = Ėₘain + Ėᵣesp + Ėdiss. The energy ratio η = Ėᵣesp / Ėₘain controls the balance between kinetic and potential energy; resonance occurs when η = 1, maximizing energy efficiency. Yang's Minimum Time Principle Δtₘin = dₘin / vₘax gives a fundamental upper bound on vibrational frequency. For atomic lattices, the Nyquist-Shannon sampling theorem applied to the discrete carrier spacing a yields the Debye frequency ωD = π vₛ / a without free parameters. Vibrational decay (damping) is interpreted as inertial leakage; for thermally activated processes the quality factor Q scales as Q ∝ exp (Eb / kB T), with the understanding that other dissipation mechanisms may yield different scaling laws. Coupled oscillators exhibit optimal energy transfer when their frequencies are commensurate (integer ratios), a manifestation of the parameter nesting principle. The EET description is valid only when kB T ≪ Eb; beyond the thermal melting limit, coherent vibration ceases. Testable predictions with explicit statistical criteria are proposed for nanoresonator frequency limits, temperature dependence of Q, commensurability effects, and the Debye frequency formula.
Hongpu Yang (Sun,) studied this question.
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