What is the electron actually doing between measurements? We propose a concrete answer: the electron is a point particle executing ultra-rapid oscillations at a characteristic frequency ωₑ = (mₑc²/ħ) ×√2 ≈ 1. 10 × 10²¹ Hz — a frequency derived from the fractal-temporal Lagrangian (not postulated), where the factor √2 follows from the kinetic parameter α = 2 uniquely fixed by the Newtonian limit. This frequency lies three orders of magnitude beyond current attosecond resolution, explaining why the oscillations appear as quantum randomness. The model derives rather than postulates three central features of quantum mechanics. The de Broglie wavelength λ = h/p emerges from a Lorentz boost of the vibrational frequency to the lab frame. The Heisenberg uncertainty relation emerges as a Fourier constraint on the unresolved vibrational dynamics. Atomic energy levels emerge as resonance conditions between the electron's vibrational frequency and the nuclear Coulomb potential. The Zitterbewegung predicted by Schrödinger in 1930 (frequency ωZB = 2mₑc²/ħ) is identified as the first harmonic (n = 1) of the fundamental frequency ωₑ, since ωZB = √2 × ωₑ. The Dirac equation captures the first harmonic but not the fundamental — the prediction is specific: the full vibrational spectrum consists of modes at ωₑ, √2 ωₑ, 2ωₑ, 2√2 ωₑ,. . . with amplitudes suppressed by (√2) ^−n. Three self-regulation mechanisms prevent unbounded vibrational energy: (1) the fractal Planck frequency as a hard upper bound, (2) temporal inertia — a negative feedback loop unique to the fractal-temporal framework where increasing frequency slows local time flow, creating self-damping, and (3) fractal dissipation through gravitational radiation and pair creation at threshold. The equilibrium frequency ωₑ is the balance point determined by these mechanisms. Nuclear-electronic harmonic cascades bridge the MeV-eV gap through ~53 levels of √2-scaling, connecting strong and electromagnetic physics through the same fractal tower that resolves the hierarchy problem in the companion electroweak and QFT papers. Testable predictions include: ultra-fast deviations from quantum mechanics at measurement timescales approaching Tₑ ≈ 5. 7 × 10⁻²¹ s, (√2) ⁿ harmonic patterns in precision spectroscopy (particularly Mössbauer transitions and the ²²⁹Th nuclear clock), and vibrational signatures in strong-field ionization. Falsification criteria are explicit.
Thierry Marechal (Fri,) studied this question.