A Resonance-Based Model of Matter and Field Structure in the Vacuum

This work proposes a unified physical model in which all observablephenomena—matter, gravity, kinetic energy, temperature, electricity,magnetism and light—emerge from resonant dynamics of a continuousvacuum field. The vacuum is treated as an elastic lattice capable of storing,transmitting and reorganizing energy through local phase oscillations.Stable material particles correspond to standing-wave configurationscharacterized by discrete pairs of integers (n,m)(n,m)(n,m), while gravityarises from the geometric deformation produced by accumulated resonances.Kinetic energy is interpreted as a coherent phase shift inside a movingresonance, whereas temperature results from its decoherent component.Electric and magnetic phenomena are described in terms of amplitudeimbalances and phase reorganizations between neighboring resonances.Light appears as free-phase energy released when a resonance losesstability. The model reproduces the periodicity of chemical elements as families ofstable (n,m)(n,m)(n,m) configurations and naturally predicts the existence oftransient, exotic, and electromagnetically silent resonances. Large-scalecosmic structures are shown to arise from the same principles, includinggravitational aggregation, stellar ignition, nuclear rearrangement,supernova cascades and galaxy-scale standing-wave modes. The presented framework does not contradict observational physics butoffers a coherent reinterpretation of its mechanisms through the lens ofresonant dynamics. The author hopes this work may stimulate furthermathematical development and experimental exploration of resonance-basedunified models.