Electron-Specific Manifestation of the Planck Constant: Conceptual Framework and Effective Quantum Scales v2

This study investigates how the universal Planck constant ((\hbar)) manifests in electron-specific effective quantum scales. While (\hbar) remains fundamentally universal, its physical realization depends on particle properties such as mass, charge, and interactions with the quantum vacuum. By analyzing key electron observables—including Compton wavelength, characteristic time, anomalous magnetic moment ((g-2)), and the Lamb shift—this work provides a conceptual framework linking fundamental constants with measurable phenomena. The approach emphasizes conceptual clarity without altering established quantum mechanics, and is fully consistent with high-precision experimental data. This framework highlights the distinction between universality and phenomenological manifestation, offering insights applicable to future studies of particle-specific quantum effects.