Developing a Complete AI-Accelerated Workflow for Superconductor Discovery
Abstract
The quest to identify new superconducting materials with enhanced properties is hindered by the prohibitive cost of computing electron-phonon spectral functions, severely limiting the materials space that can be explored. Here, we introduce a Bootstrapped Ensemble of Equivariant Graph Neural Networks (BEE-NET), a machine-learning model trained to predict the Eliashberg spectral function and superconducting critical temperature with a mean-absolute-error of 0.87 K relative to DFT-based Allen-Dynes calculations. Intriguingly, BEE-NET achieves a true-negative-rate of 99.4\%, enabling highly efficient screening for the rare property of superconductivity. Integrated into a multi-stage, AI-accelerated discovery pipeline that incorporates elemental-substitution strategies and machine-learned interatomic potentials, our workflow reduced over 1.3 million candidate structures to 741 dynamically and thermodynamically stable compounds with DFT-confirmed K. We report the successful synthesis and experimental confirmation of superconductivity in two of these previously unreported compounds. This study establishes a data-driven framework that integrates machine learning, quantum calculations, and experiments to systematically accelerate superconductor discovery.
Keywords
Cite
@article{arxiv.2503.20005,
title = {Developing a Complete AI-Accelerated Workflow for Superconductor Discovery},
author = {Jason B. Gibson and Ajinkya C. Hire and Pawan Prakash and Philip M. Dee and Benjamin Geisler and Jung Soo Kim and Zhongwei Li and James J. Hamlin and Gregory R. Stewart and P. J. Hirschfeld and Richard G. Hennig},
journal= {arXiv preprint arXiv:2503.20005},
year = {2026}
}
Comments
10 pages, 5 figures