Microstructure-based Variational Neural Networks for Robust Uncertainty Quantification in Materials Digital Twins
Abstract
Aleatoric uncertainties - irremovable variability in microstructure morphology, constituent behavior, and processing conditions - pose a major challenge to developing uncertainty-robust digital twins. We introduce the Variational Deep Material Network (VDMN), a physics-informed surrogate model that enables efficient and probabilistic forward and inverse predictions of material behavior. The VDMN captures microstructure-induced variability by embedding variational distributions within its hierarchical, mechanistic architecture. Using an analytic propagation scheme based on Taylor-series expansion and automatic differentiation, the VDMN efficiently propagates uncertainty through the network during training and prediction. We demonstrate its capabilities in two digital-twin-driven applications: (1) as an uncertainty-aware materials digital twin, it predicts and experimentally validates the nonlinear mechanical variability in additively manufactured polymer composites; and (2) as an inverse calibration engine, it disentangles and quantitatively identifies overlapping sources of uncertainty in constituent properties. Together, these results establish the VDMN as a foundation for uncertainty-robust materials digital twins.
Cite
@article{arxiv.2512.18104,
title = {Microstructure-based Variational Neural Networks for Robust Uncertainty Quantification in Materials Digital Twins},
author = {Andreas E. Robertson and Samuel B. Inman and Ashley T. Lenau and Ricardo A. Lebensohn and Dongil Shin and Brad L. Boyce and Remi M. Dingreville},
journal= {arXiv preprint arXiv:2512.18104},
year = {2025}
}
Comments
43 pages, 9 figures,