Beyond Diamond: Interpretable Machine Learning Reveals Design Principles for Quantum Defect Host Materials

Abstract

Solid-state spin defects in wide-bandgap semiconductors are leading candidates for quantum information processing, but systematic identification of suitable host materials remains limited by the cost of first-principles screening across vast chemical spaces. We address this with a composition-only machine learning framework built on heterogeneous Rashomon set ensembles: by contrasting the feature attributions of seven diverse classifiers, we extract consensus design rules that no single model identifies alone-filled valence s-, d-, and f-shells, low chemical heterogeneity, and enrichment in C, S, Si, and O favor quantum compatibility. Screening approximately 45,000 thermodynamically stable compounds, we identify 122 high-confidence candidates (confidence > 0.95), recovering most experimentally verified hosts (C, SiC, ZnO, ZnS) and predicting unexplored materials including TiO2, PbWO4, and layered chalcogenides (HfS2, ZrS2). Density functional perturbation theory calculations on 12 representative materials validate dielectric screening as a coherence proxy (R2 = 0.89 against experimental T2), and vacancy calculations for TiO2 reveal deep, isolated mid-gap states favorable for spin-defect hosting. The framework provides transferable, physically grounded design principles for rational quantum materials discovery beyond traditional carbide and nitride hosts.