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

Materials Science 2026-05-20 v3

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_2, PbWO4_4, and layered chalcogenides (HfS2_2, ZrS2_2). Density functional perturbation theory calculations on 12 representative materials validate dielectric screening as a coherence proxy (R2^2 = 0.89 against experimental T2_2), and vacancy calculations for TiO2_2 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.

Keywords

Cite

@article{arxiv.2506.03844,
  title  = {Beyond Diamond: Interpretable Machine Learning Reveals Design Principles for Quantum Defect Host Materials},
  author = {Mohammed Mahshook and Rudra Banerjee},
  journal= {arXiv preprint arXiv:2506.03844},
  year   = {2026}
}

Comments

16 pages including references, 8 figures

R2 v1 2026-07-01T02:58:50.355Z