磁制冷
无定形固体
材料科学
凝聚态物理
热力学
熵(时间箭头)
非晶态金属
高熵合金
统计物理学
冶金
物理
磁场
磁化
微观结构
化学
结晶学
合金
量子力学
作者
Yichuan Tang,Shengang Li,Sen Liu,Ruonan Ma,P Y Li,Pan Lin,Kun Wang,Chao Zhou,Kaiyan Cao,Tieyan Chang,Minxia Fang,Yin Zhang
摘要
Accurate prediction of magnetic phase-transitions is essential for the applicability of the magnetocaloric effect. Despite the demonstrable efficacy of machine learning in addressing such issues, existing strategies remain constrained to specific material categories, exhibiting limited generalizability across diverse systems. Herein, we propose a multi-model ensemble framework that overcomes the limitations of the conventional single-model paradigm in NiMnFeCoBP high-entropy-amorphous-alloys. The integration of complementary methodologies has yielded a 9%–13% increase in prediction accuracy when utilizing an ensemble model compared with single models. This adaptive strategy effectively resolves the accuracy-generality trade-off dilemma in materials informatics by leveraging the collective strengths of multiple predictive models.
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