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Data‐Driven Design of Mechanically Hard Soft Magnetic High‐Entropy Alloys

Mian Dai, Yixuan Zhang, Xiaoqing Li, Stephan Schönecker, Liuliu Han, Ruiwen Xie, Chen Shen, Hongbin Zhang

2025Advanced Science10 citationsDOIOpen Access PDF

Abstract

The design and optimization of mechanically hard soft magnetic materials, which combine high hardness with magnetically soft properties, represent a critical frontier in materials science for advanced technological applications. To address this challenge, a data-driven framework is presented for exploring the vast compositional space of high-entropy alloys (HEAs) and identifying candidates optimized for multifunctionality. The study employs a comprehensive dataset of 1 842 628 density functional theory calculations, comprising 45 886 quaternary and 414 771 quinary equimolar HEAs derived from 42 elements. Using ensemble learning, predictive models are integrated to capture the relationships between composition, crystal structure, mechanical, and magnetic properties. This framework offers a robust pathway for accelerating the discovery of next-generation alloys with high hardness and magnetic softness, highlighting the transformative impact of data-driven strategies in material design.

Topics & Concepts

QuinaryHigh entropy alloysMaterials scienceDensity functional theoryMaterial DesignNanotechnologyTransformative learningEntropy (arrow of time)Computer scienceMicrostructureThermodynamicsMetallurgyAlloyPhysicsComposite materialPedagogyQuantum mechanicsPsychologyHigh Entropy Alloys StudiesMachine Learning in Materials ScienceAdvanced materials and composites
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