MiAD Crystal Generation (Mirage Atoms)

DEVELOPED FOR
Materials R&D labs, deep-tech startups (batteries, semiconductors, pharma), and generative-AI research groups

The challenge

  • Discovering new stable crystalline materials is crucial for batteries, semiconductors, catalysts, and pharmaceuticals.
  • Diffusion models (DiffCSP, MatterGen) lead the field but are restricted to a fixed number of atoms during generation.
  • Fixed atom count limits trajectory flexibility and hinders exploration of plausible crystal structures.

The Solution

  • MiAD: a joint diffusion model for de novo crystal generation that can change the number of atoms during generation.
  • Core technique — mirage infusion: placeholder atoms (type 0) that materialize into real atoms or vanish during denoising.
  • Drop-in augmentation for any joint diffusion model (DiffCSP-style); preserves crystal symmetries and equivariance.

Core innovations:

  • Mirage atom type: New discrete type “0” lets the model freely materialize or annihilate atoms during generation.
  • Infusion + masked loss: Real crystals augmented with extra mirage atoms; coordinate loss masked so the model places them freely.

Impact

Industrial Directions

  • Materials science and crystal structure prediction.
  • Battery, semiconductor, and catalysis R&D.
  • Diffusion research for structured, variable-size data (crystals, molecules, graphs).

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

Join our team working on cutting-edge autonomous transport systems. Explore opportunities in machine learning, computer vision, and robotics.

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