Landscape of Thermodynamic Stabilities of A2BB′O6 Compounds

Perovskite oxides have been extensively studied for their wide range of compositions and structures, as well as their valuable properties for various applications. Expanding from single-perovskite ABO3 to double-perovskite A2BB′O6 significantly enhances the ability to tailor specific physical and chemical properties. However, the vast number of potential compositions of A2BB′O6 makes it impractical to explore all of them experimentally. In this study, we conducted high-throughput calculations to systematically investigate the structures and stabilities of 4900 A2BB′O6 compositions (with A = Ca, Sr, Ba, and La; B and B′ representing metal elements) through over 42 000 density functional theory (DFT) calculations. Our analysis lead to the discovery of more than 1500 new thermodynamically stable A2BB′O6 compounds, with over 1100 of them exhibiting double perovskite structures, predominantly in the P21/c space group. By leveraging the high-throughput dataset, we developed machine learning models that achieved mean absolute errors of 0.0422 and 0.0329 eV/atom for formation energy and decomposition energy, respectively. Using these models, we identified 803 stable or metastable compositions beyond the chemical space covered in our initial calculations, with 612 of them having DFT-validated decomposition energies below 0.1 eV/atom, resulting in a success rate of 76.2%. This study delineates the stability landscape of A2BB′O6 compounds and offers new insights for exploration of these materials.