Definition:
The Electron Engineering Codex governs the manipulation, structuring, and application of electrons in designed systemsβfrom circuits to quantum frameworksβbridging fundamental particle behavior with complex system architectures.
Core Components:
- Particle Dynamics Layer:
Tracks charge, spin, and energy exchange at the quantum and classical levels for conduction, insulation, and field interactions. - Conduction & Flow Protocols:
Covers electron pathfinding in conductors, semiconductors, and superconductors. Encodes protocols for drift velocity, band theory, and tunneling phenomena. - Circuit Architectonics:
Modular templates and blueprint structures for analog and digital circuit designβfrom CMOS to GaN to photonic-electronic hybrids. - Electron Behavior Simulation Matrix:
Real-time modeling of multi-electron systems under varying field and temperature constraints. Supports SchrΓΆdinger-Poisson and Hartree-Fock simulations. - Energy Field Harmonization:
Ensures aligned flow of electron vectors with electromagnetic field gradients. Integrates inductive/capacitive balance and parasitic minimization strategies. - Thermal-Electric Integration:
Links electron movement with Joule heating, thermoelectric conversion (Seebeck/Peltier effects), and advanced cooling solutions.
Linked Codices:
- Quantum Codex β For spin states, superposition, and entanglement applications.
- Photonics Codex β Where electrons interact with or emit/absorb light (e.g., LEDs, lasers).
- Signal Codex β For transmission of electrical signals via electron carriers.
- Resonance Codex β To stabilize and amplify electron oscillations at desired frequencies.
Applications:
- Semiconductor device fabrication
- Superconductor array design
- Microchip architecture and embedded systems
- Electrical propulsion and energy harvesting
- Quantum dot and single-electron transistor development