Quantum Spin Chain ML (SDRG-GNN)

DEVELOPED FOR
Condensed-matter physics groups, quantum-information labs, and scientific-ML research (physics-informed models for disordered systems)

The challenge

  • Modeling entanglement in disordered long-range interacting quantum spin chains is computationally expensive.
  • Exact diagonalization and DMRG scale poorly to large systems with long-range couplings.
  • Strong-disorder RG (SDRG) is powerful but slow, and finite-temperature extensions (SDRG-X) add further cost.

The Solution

  • ML models trained on SDRG as a physics-informed teacher to infer entanglement structure of disordered spin chains.
  • Graph Neural Network (GNN) operates on the interaction graph and learns a bond-ranking rule mirroring SDRG decimation.
  • Random Forest baseline for comparison; two-stage zero-T + thermal-sampling handles finite-T.

Core innovations:

  • Physics-informed teacher: SDRG supervises the GNN at every RG step, not just final-state observables.
  • Scale-invariant GNN: Edge-centric message passing with local normalization for SDRG-style scale invariance.
  • Finite-T: Zero-T GNN + canonical sampling, no retraining.

Impact

Industrial Directions

  • Condensed-matter and quantum many-body physics.
  • Quantum information and entanglement-based diagnostics.
  • Physics-informed scientific ML and graph-based simulators.

Research Team

Meet Our PIs

Discover the principal investigators behind this project and the expertise that made it possible.

Prof. Dr. Andrey Ustyuzhanin

Open Vacancies

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