Litcius/Paper detail

Self-optimizing machine learning potential assisted automated workflow for highly efficient complex systems material design

Jiaxiang Li, Junwei Feng, Jie Luo, Bowen Jiang, Xiangyu Zheng, Qi Song, Jian Lv, Keith T. Butler, Hanyu Liu, Congwei Xie, Yu Xie, Yanming Ma

2026npj Computational Materials6 citationsDOIOpen Access PDF

Abstract

Abstract Machine learning interatomic potentials have revolutionized complex materials design by enabling rapid exploration of material configurational spaces via crystal structure prediction with ab initio accuracy. However, critical challenges persist in ensuring robust generalization to unknown structures and minimizing the requirement for substantial expert knowledge and time-consuming manual interventions. Here, we propose an automated crystal structure prediction framework built upon the attention-coupled neural network potential to address these limitations. The generalizability of the potential is achieved by sampling regions across the local minima of the potential energy surface, where the self-evolving pipeline autonomously refines the potential iteratively while minimizing human intervention. The workflow is validated on Mg-Ca-H ternary and Be-P-N-O quaternary systems by exploring nearly 10 million configurations, demonstrating substantial speedup compared to first-principles calculations. These results underscore the effectiveness of our approach in accelerating the exploration and discovery of complex multi-component functional materials.

Topics & Concepts

WorkflowComputer scienceMaxima and minimaPipeline (software)Artificial intelligenceMachine learningComplex systemGeneralizationCrystal structure predictionArtificial neural networkCASPGeneralizability theoryFlexibility (engineering)Interatomic potentialData miningSpeedupAb initioDomain (mathematical analysis)Bayesian optimizationDeep learningProtein structure predictionSystems designEnergy (signal processing)Energy minimizationSampling (signal processing)Parameterized complexityTernary operationMachine Learning in Materials ScienceInorganic Chemistry and MaterialsX-ray Diffraction in Crystallography