The complete research archive behind Time Ledger Theory. Theory documents, research studies, cross-domain maps, validation data, simulation code, and raw results — all browsable and downloadable.
Core theoretical framework documents: the mathematical framework, dimensional progression model, cipher iterations (v1 through v11), and computational derivation scripts for C_potential, framerate compression, and Fibonacci convergence.
Individual research studies covering cosmology, dark matter, dark energy, quantum mechanics, particle geometry, materials science, neurology, protein folding, galaxy pitch angles, heavy metals, quasicrystals, speed of light, tunneling, music theory, and more.
Broad literature and technology surveys across cosmology, frequency computing, fusion, geometry, informatics, lasers/plasma, materials science, neuroscience, quantum mechanics, and fringe technology.
Maps showing how Time Ledger Theory connects to different scientific fields. Each document traces the theory's predictions and explanations across a specific domain, from 2D materials and biology to cosmology, neurology, and meta-level physics.
Research into fourth-dimensional physics: the 24-cell geometry, D4 triality, 5D crystal lattice projections, cipher dual-track processing, mathematical framework extensions, test descriptions, audit reports, engine code, and radial map analyses.
Eigenvalue spectra analysis across all crystal geometries, susceptibility framework, HPC lattice resonance and designed geometry results, sphere resonance findings, and the cipher-to-eigenvalue connection.
Geometric alternative to dark matter: framerate gradient theory notes, galactic settling analysis, test description, correlation computation code, and raw correlation results from galaxy rotation curve analysis.
Complete validation pipeline for the geometric cipher: validation scripts, engine code, blind sweep predictions, scoring results across cipher versions v6 through v9, audit reports, gap analyses, stress tests, crossover evaluations by external AI models (Gemini, Grok), and full periodic table data.
Active research into cold plasma frequency isolation and geometric expression at higher dimensional depths. We are investigating whether specific geometric cavities, when driven at frequencies corresponding to dimensional transition ratios, can be nudged into deeper dimensional states — effectively using geometry and frequency together to access physics that neither alone can reach.
Current areas of exploration:
Targeted literature probes testing specific TLT predictions against published research: actinide resistivity, icosahedral cavity resonance, polyhedral cavity acoustics, f-electron geometry, 24-cell mainstream convergence, Wigner-Seitz void resonance, helium dimensional boundary, and PeV dimensional boundary.
SIM-003 v6c simulation engine with wave re-injection, CMB comparison code, grid convergence testing, overtone analysis, periodic table sweep, and HPC deployment scripts for the Hetzner compute cluster.