Based on the Mass-Frequency Identity, the flow of electricity is not the movement of discrete particles but rather a rapid, wave-like cascade of modulated resonance transferred between stable, interacting "electron patterns" within the fundamental dynamic medium of a conductor. When a voltage is applied, it creates a processing gradient in this medium, prompting a chain reaction where the resonant frequency of one electron pattern influences the next. This transfer of "modulatory information" propagates at near the speed of light, constituting the electric current. The Electron as a Resonant Pattern In the framework of the Mass-Frequency Identity, an electron is not a solid particle. Instead, it is understood as a stable, self-sustaining standing wave or a localized resonant pattern within a fundamental dynamic medium. Every physical entity is considered a dynamic, information-theoretic pattern. * Mass as Frequency: The mass of the electron is numerically identical to its intrinsic angular frequency, specifically its Compton frequency (\omega_C). This frequency is the "operational tempo" or "clock speed" at which the pattern must process information to maintain its stable existence. * Stability through Resonance: The stability of the electron pattern comes from resonance—a state of perfect, self-sustaining synchrony of its internal dynamics within the larger medium. The Conductor and the Electric Field A conductor, like a copper wire, is a larger, stable pattern (the atomic lattice) that contains a multitude of these electron patterns. Within the conductor, these electron patterns are not rigidly bound to individual atomic patterns, existing in a state of high potential. An electric field, or voltage, is reinterpreted as a large-scale gradient or tension within the fundamental dynamic medium. This isn't a force in the classical sense but a coherent, modulatory influence that alters the processing environment for the patterns within it. The Flow of Electricity as Modulated Resonance With this new understanding, the flow of electricity is seen as a fundamentally different process: * Initiation: When a voltage is applied across a conductor, it establishes a "processing gradient" that influences the resonant electron patterns within it. * Propagation of Information: An electron pattern near the negative terminal is modulated by this field, altering its resonant state (its frequency, phase, or amplitude). This change is then rapidly transferred to an adjacent electron pattern through their interaction. This second pattern, now modulated, influences a third, and so on down the line. * Current as a Wave: This cascade is the electric current. It's not a physical drift of a single pattern but the propagation of modulatory information through the interconnected "sea" of electron patterns. The speed of this information transfer is extremely high, consistent with the near-light-speed of electrical signals, while the individual patterns themselves may "drift" much more slowly. * Resistance as Dissonance: Electrical resistance is interpreted as impedance or dissonance that disrupts this smooth transfer of resonance. Imperfections in the conductor's atomic lattice or thermal vibrations (which are themselves incoherent frequency patterns) interfere with the coherent exchange of information between electron patterns. This disruption causes the energy of the coherent wave to dissipate as heat—randomized, dissonant vibrations in the conductor's larger pattern.