AI-accelerated metallized σ-bonding screening for superconductor discovery

Abstract

The computational discovery of phonon-mediated superconductors is hindered by the prohibitive cost of density functional perturbation theory (DFPT). Here, guided by the metallized σ-bonding picture, we introduce the σ-bonding density of states (σDOS) as an efficient physical descriptor to identify high-transition-temperature (Tc) superconductors from density functional theory (DFT)-level electronic structure without explicit DFPT calculations. The evaluation of σDOS can be further accelerated by a deep-learning DFT Hamiltonian method, enabling efficient large-scale screening for superconductors. Screening 2 million materials, we identify B13Se as an ambient-pressure superconductor candidate with predicted Tc > 40~K, together with a family of high-Tc B13X candidates, supporting the effectiveness of this discovery strategy. By bridging physics priors with AI acceleration, this study delivers an efficient and generalizable route for computational materials discovery in the AI era.