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Machine learning assisted composition design of high-entropy Pb-free relaxors with giant energy-storage

Xingcheng Wang, Ji Zhang, Xiaohan Ma, Huajie Luo, Laijun Liu, Hui Liu, Jun Chen

2025Nature Communications35 citationsDOIOpen Access PDF

Abstract

Abstract The high-entropy strategy has emerged as a prevalent approach to boost capacitive energy-storage performance of relaxors for advanced electrical and electronic systems. However, exploring high-performance high-entropy systems poses challenges due to the extensive compositional space. Herein, with the assistance of machine learning screening, we demonstrated a high energy-storage density of 20.7 J cm -3 with a high efficiency of 86% in a high-entropy Pb-free relaxor ceramic. A random forest regression model with key descriptors based on limited reported experimental data were developed to predict and screen the elements and chemical compositions of high-entropy systems. Following basic experiments, a (Bi 0.5 Na 0.5 )TiO 3 -based high-entropy relaxor characterized by fine grains, weakly-coupled and small-sized polar clusters was identified. This resulted in a near-linear polarization behavior and an ultrahigh breakdown strength of 95 kV mm -1 . Further, this high-entropy realxor presented a high discharge energy density of 7.7 J cm -3 under discharge rate of about 27 ns, along with superior temperature and fatigue stability. Our results present the data-driven model for efficiently exploring high-performance high-entropy relaxors, demonstrating the potential of machine learning in developing relaxors.

Topics & Concepts

Entropy (arrow of time)Materials scienceEnergy storageComputer scienceStatistical physicsThermodynamicsMachine learningPhysicsPower (physics)Ferroelectric and Piezoelectric MaterialsElectronic and Structural Properties of OxidesMagnetic and transport properties of perovskites and related materials
Machine learning assisted composition design of high-entropy Pb-free relaxors with giant energy-storage | Litcius