Emergent Quantum Mechanics from Discrete Lattice Dynamics
A complete derivation of quantum mechanics, quantum field theory, and their unification with the Standard Model and gravity — from Conscious Point Physics primitives on the 600-cell lattice.
Series Overview
In Conscious Point Physics (CPP), quantum mechanics emerges statistically from discrete primitives — Conscious Points (CPs), Grid Points (GPs) in the 600-cell lattice, Displacement Increment (DI) bits, and the Nexus — without fundamental wavefunctions, probabilities, or Hilbert spaces.
This 7-paper series systematically derives every major quantum phenomenon from geometric first principles, resolving all foundational puzzles (measurement problem, non-locality, renormalization, quantum gravity) while maintaining 99.7–99.9% agreement with standard QM across all energy scales. No free parameters beyond Planck units and cosmic site count \(N \approx 10^{61}\).
Papers — 7 papers · CPP-041 through CPP-047
Quantum Mechanics Emergence from Discrete Lattice Dynamics — Complete Series Overview
Overview of the 7-paper QM series. Introduces how superposition, entanglement, collapse, QFT, and gravity all emerge from 600-cell lattice dynamics and DI bit flows.
Emergent Wave-Particle Duality and the Schrödinger Equation from DI Bit Flows
Derives wave-particle duality and the time-dependent Schrödinger equation as the continuum limit of DI bit diffusion under SSV potentials on the 600-cell lattice.
Superposition and Interference from Lattice Phase Coherences
Quantum superposition emerges from coherent multi-path DI bit flows across 600-cell subgraphs. Derives the Born rule from amplitude modulus without postulating probability.
Entanglement and Bell’s Inequalities from Shared Nexus Conservation
Entanglement arises from shared DI bit quanta conserved via the atemporal Nexus. Derives CHSH violation up to 2√2 from geometric phase relationships on the lattice.
Measurement Problem and Apparent Collapse from Bit-Sea Thermalization
Resolves the measurement problem as objective decoherence from bit-sea scattering. No collapse postulate, observer role, or many-worlds branching required.
Emergent Quantum Field Theory and Renormalization from Lattice Bit Modes
QFT emerges from excitations of DI bits in the bit-sea. Renormalization is naturally resolved through lattice cutoffs, eliminating UV divergences without arbitrary regulators.
Full Quantum Unification with the Standard Model and Gravity
Capstone synthesis of the QM series with Electroweak and Strong series. Wavefunctions, fields, particles, forces, and spacetime curvature all derive from bit dynamics and lattice geometry.
Emergence Hierarchy
| Paper | Phenomenon | Mechanism | Resolves |
|---|---|---|---|
| #1 (041) | Series Overview | Full emergence hierarchy | Framework introduction |
| #2 (042) | Wave-particle duality | DI bit diffusion on geodesics | Wavefunction origin |
| #3 (043) | Superposition & interference | Multi-path lattice coherence | Born rule derivation |
| #4 (044) | Entanglement | Shared Nexus conservation | Bell non-locality |
| #5 (045) | Measurement & collapse | Bit-sea thermalization | Measurement problem |
| #6 (046) | QFT & renormalization | Lattice bit modes & cutoffs | UV divergences |
| #7 (047) | Full unification | Geometric synthesis | QM + SM + Gravity |