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Data-Driven Perovskite Design via High-Throughput Simulation and Machine Learning

Yidi Wang, Dan Sun, Bei Zhao, Tianyu Zhu, Chengcheng Liu, Zixuan Xu, Tianhang Zhou, Chunming Xu

2025Processes6 citationsDOIOpen Access PDF

Abstract

Perovskites (ABX3) exhibit remarkable potential in optoelectronic conversion, catalysis, and diverse energy-related fields. However, the tunability of A, B, and X-site compositions renders conventional screening methods labor-intensive and inefficient. This review systematically synthesizes the roles of physical simulations and machine learning (ML) in accelerating perovskite discovery. By harnessing existing experimental datasets and high-throughput computational results, ML models elucidate structure-property relationships and predict performance metrics for solar cells, (photo)electrocatalysts, oxygen carriers, and energy-storage materials, with experimental validation confirming their predictive reliability. While data scarcity and heterogeneity inherently limit ML-based prediction of material property, integrating high-throughput computational methods as external mechanistic constraints—supplementing standardized, large-scale training data and imposing loss penalties—can improve accuracy and efficiency in bandgap prediction and defect engineering. Moreover, although embedding high-throughput simulations into ML architectures remains nascent, physics-embedded approaches (e.g., symmetry-aware networks) show increasing promise for enhancing physical consistency. This dual-driven paradigm, integrating data and physics, provides a versatile framework for perovskite design, achieving both high predictive accuracy and interpretability—key milestones toward a rational design strategy for functional materials discovery.

Topics & Concepts

Artificial intelligenceMachine learningComputer sciencePerovskite (structure)EmbeddingPredictive modellingLimit (mathematics)Computational modelScarcityExperimental dataTraining setData-drivenComputational simulationMaterials scienceComputational learning theoryNanotechnologyData modelingPerovskite Materials and ApplicationsMachine Learning in Materials ScienceElectronic and Structural Properties of Oxides