Document unsolved superconductivity physics problems

[scottsen]

Create comprehensive strategic document outlining how Morphogen can address the four fundamental gaps in superconductivity physics:

1. Strongly correlated electrons - no predictive microscopic theory
2. Predictive design rules - cannot design superconductors systematically
3. High-pressure hydrides beyond BCS - understanding anharmonicity
4. Interacting orders & flat-band physics - unified treatment

Proposes Condensed Matter Physics (CMP) Suite with 7 new domains:

• QuantumDomain: Tight-binding, band structure, Fermi surfaces
• LatticePhononDomain: Phonons, anharmonicity, electron-phonon coupling
• ManyBodyDomain: Correlated electrons, DMFT, QMC
• TopologyDomain: Berry curvature, topological invariants
• MagneticOrderDomain: Spin models, magnetic phases
• MaterialsDesignDomain: Inverse design, parameter exploration
• SuperconductivityDomain: Pairing analysis, Tc estimation

Key advantages of Morphogen for this application:

• Multi-domain integration (electronics + phonons + optimization)
• Deterministic execution for reproducible science
• Type-safe physical units
• MLIR compilation for performance
• Unified computational environment

Includes 6-phase implementation roadmap spanning ~18 months, validation strategy, and vision for transforming computational materials discovery from post-hoc explanation to predictive design.

This validates Morphogen for professional scientific computing and demonstrates the platform's unique value proposition.