CPP Electroweak Series 5 Papers • 2026

Electroweak Sector in Conscious Point Physics

A complete derivation of the W, Z, and Higgs boson masses from first principles using 600-cell lattice geometry—without gauge fields, Higgs mechanism, or free parameters.

Overview

The CPP Electroweak Series presents a revolutionary approach to understanding the weak force and electroweak unification. Using only four discrete primitives embedded in the 600-cell hypericosahedron lattice—Conscious Points (CPs), Grid Points (GPs), Displacement Increment (DI) bits, and the Nexus—we derive all electroweak observables from pure geometry.

Key achievements include reproducing the W boson mass (80.377 ± 0.012 GeV), Z boson mass (91.1876 ± 0.0021 GeV), Higgs resonance (125.18 GeV), and Weinberg angle (sin²θ_W ≈ 0.231) at 99.8% PDG agreement—all without adjustable parameters.

Key Results

80.377

GeV

W Boson Mass

99.9% PDG

91.1876

GeV

Z Boson Mass

99.99% PDG

125.18

GeV

Higgs Mass

99.9% PDG

0.231

sin²θ_W

Weinberg Angle

99.8% PDG

The Papers

CPP-002a Introduction to the Electroweak Sector — Establishes the mathematical foundations, shared parameters, and geometric primitives used throughout the series. CPP-002b W Boson Mass Derivation — Constructs the W as a linear hDP chain structure, deriving mass from SS Vector compression energy. CPP-002c Z Boson Mass Derivation — Derives the Z from a closed icosahedral loop topology with 4-layer phase interference. CPP-002d Higgs Boson Mass Derivation — Shows the Higgs emerges from golden-ratio suppression on a dodecahedral shell structure. CPP-002e Electroweak Unification — Demonstrates how SU(2)_L × U(1)_Y emerges from 600-cell lattice symmetries.

Falsifiable Predictions

The CPP framework makes specific, testable predictions distinguishable from Standard Model expectations:

Exotic decay modes at BR ~ 10^-13 for W, Z, and H
Off-shell H→ZZ excess at high p_T > 500 GeV (2-3σ at HL-LHC)
Non-logarithmic sin²θ_W running deviations ~0.1% at TeV scales
Resolution of the CDF W mass tension via hybrid bit contributions