A Foundation Model for Non-Destructive Defect Identification from Vibrational Spectra
Oral-In-person
Abstract
Defects are ubiquitous in solids and strongly influence materials’ mechanical and functional properties. However, non-destructive characterization and quantification of defects, especially when multiple types coexist, remain a long-standing challenge. Here we introduce DefectNet, a foundation machine learning model that predicts the chemical identity and concentration of substitutional point defects with multiple coexisting elements directly from vibrational spectra, specifically phonon density-of-states (PDoS). Trained on over 16,000 simulated spectra from 2,000 semiconductors, DefectNet employs a tailored attention mechanism to identify up to six distinct defect elements at concentrations ranging from 0.2% to 25%. The model generalizes well to unseen crystals across 56 elements and can be fine-tuned on experimental data. Validation using inelastic scattering measurements of SiGe alloys and MgB2 superconductor demonstrates its accuracy and transferability. Our work establishes vibrational spectroscopy as a viable, non-destructive probe for point defect quantification in bulk materials, and highlights the promise of foundation models in data-driven defect engineering.
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Publication: Cheng, M., Fu, C.L., Yu, B., Rha, E., Chotrattanapituk, A., Abernathy, D.L., Cheng, Y. and Li, M., 2025. A Foundation Model for Non-Destructive Defect Identification from Vibrational Spectra. arXiv preprint arXiv:2506.00725.
Presenters
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Mouyang Cheng
- Massachusetts Institute of Technology