The Ultronic Medium Hypothesis (UMH) proposes that all known physical phenomena โ from particles and gravity to time and magnetism โ arise from vibrational waveforms within a structured, continuous medium.
It offers a unifying, mechanical perspective on quantum and relativistic physics, providing deep conceptual insights and simulation-backed validation.
UMH beneath General Relativity, QFT, and the Standard Model.Key concepts: solitons, pressure gradients, EM waves.The medium as a 3D lattice of ultrons (Planck spacing).Particle modeled as a rotating soliton in the grid.Forces emerge as distortions of the ultronic medium.c, h, G, and m derived from medium parameters.Electric and magnetic waves in a transverse medium grid.Radial compression modeling gravitational attraction.
The following simulation results are direct consequences of the Ultronic Medium Hypothesis.
No arbitrary parameters, no force-fitting, and no added constants were used to shape these outcomes.
While UMH predictions are scaled to observational units where appropriate, their structure and behavior emerge
entirely from first principles โ not from tuning.
What you see here is the natural behavior of the medium under its defined mechanics, aligned across a wide range of cosmological phenomena.
3D wavefront propagation through ultronic medium โ spherical isotropic expansion.Central Z-slice showing amplitude and dispersion of wave propagation in the medium.
UMH fit vs. Hubble Law using observed galaxy redshift data.UMH model fits Type Ia supernovae data with higher accuracy than ฮCDM, especially at higher redshifts.Residuals from Pantheon supernovae data โ UMH model consistently shows smaller deviations than ฮCDM, indicating a closer match to observed distances.
Full-sky projection of strain amplitude derived from UMH simulation, highlighting natural anisotropies consistent with CMB structure.UMH power spectrum aligned with Planck TT modes โ peak dropoff visualized.UMH reproduces angular BAO peak structure and angular correlation curve.
UMH chirp model: gravitational wave strain and binary decay pattern (Hanford simulation).Spectrogram of UMH chirp from Hanford simulation โ energy rise over time.UMH vs LIGO FFT profile shows noise envelope and characteristic peaks.
Figure: UMH Soliton Scattering (Boson) โ Bosonic fields remain stable and retain core structure through scattering, indicating robust emergent soliton behavior.Figure: UMH Soliton Scattering (Fermion) โ Fermionic solitons exhibit exclusion and antisymmetric scattering behavior consistent with fermionic field properties.Figure: UMH Gauge Symmetry (U(1)) โ Ricci curvature slice (Ryy) shows field coherence and wave propagation structure consistent with electromagnetic symmetry.Figure: UMH Gauge Symmetry (SU(3)) โ Isosurface visualization reveals non-Abelian gauge-like complexity in emerging structure at early simulation steps.Figure: UMH Gravity Tensor โ Tensor-vector field emerges from UMH wave interference pattern, modeling curvature consistent with general relativity.
