Foundation Model for Polycrystalline Material Informatics

We present a 3D polycrystal foundation model that learns a physically structured representation of voxel-based microstructures through large-scale self-supervised pretraining. The encoder is trained on a dataset of 100,000 FCC microstructures whose crystallographic orientations span the texture hull, using a masking strategy that forces the model to infer latent features from incomplete spatial information. The quality of the learned representation is evaluated through two downstream tasks with distinct physical characteristics. (i) Homogenized stiffness prediction: the pretrained encoder consistently outperforms the non-pretrained baseline across all masking ratios. (ii) Nonlinear response modeling: the encoder is coupled with an orientation-aware interaction-based deep material network (ODMN) to infer complete sets of network parameters, enabling accurate stress-strain predictions for previously unseen microstructures. In both tasks, the pretrained encoder demonstrates markedly stronger generalization capability. These results underscore the strong transferability of the proposed framework and its suitability for data-scarce scientific settings, where labeled microstructures are limited and physics-consistent generalization is essential. The foundation model provides a scalable route toward integration with experimentally derived microstructures, offering a new basis for microstructure-property reasoning in practical materials design.