Superstrength permanent magnets with iron-based superconductors by data- and researcher-driven process design

IF 8.6 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Npg Asia Materials Pub Date : 2024-06-07 DOI:10.1038/s41427-024-00549-5

Akiyasu Yamamoto, Shinnosuke Tokuta, Akimitsu Ishii, Akinori Yamanaka, Yusuke Shimada, Mark D. Ainslie

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Abstract

Iron-based high-temperature (high-Tc) superconductors have good potential to serve as materials in next-generation superstrength quasipermanent magnets owing to their distinctive topological and superconducting properties. However, their unconventional high-Tc superconductivity paradoxically associates with anisotropic pairing and short coherence lengths, causing challenges by inhibiting supercurrent transport at grain boundaries in polycrystalline materials. In this study, we employ machine learning to manipulate intricate polycrystalline microstructures through a process design that integrates researcher- and data-driven approaches via tailored software. Our approach results in a bulk Ba0.6K0.4Fe2As2 permanent magnet with a magnetic field that is 2.7 times stronger than that previously reported. Additionally, we demonstrate magnetic field stability exceeding 0.1 ppm/h for a practical 1.5 T permanent magnet, which is a vital aspect of medical magnetic resonance imaging. Nanostructural analysis reveals contrasting outcomes from data- and researcher-driven processes, showing that high-density defects and bipolarized grain boundary spacing distributions are primary contributors to the magnet’s exceptional strength and stability. Iron-based superconductors are promising for uses like quantum computing and superstrong magnets. However, improving their superconducting properties is challenging. This study aimed to improve these properties in a specific superconductor, K-doped Ba122, using Bayesian optimization. The researchers made samples under different conditions and measured their superconducting properties to refine the process. Two large disk-shaped samples were made using the best processing conditions found from data-driven and researcher-driven methods. The superconducting properties of these samples, and their ability to act as magnets, were tested at low temperatures. The results showed significant improvements, proving the optimization process’s effectiveness and resulting in an iron-based superconducting magnet with unprecedented strength. The study concludes that machine learning, especially Bayesian optimization, can significantly advance high-performance superconducting materials development. This could lead to more efficient and powerful superconducting magnets for various uses. This summary was initially drafted using artificial intelligence, then revised and fact-checked by the authors. The world’s strongest iron-based superconducting magnet has been manufactured. Machine learning using Bayesian optimization was employed to improve the superconducting properties of potassium-doped barium iron arsenide (Ba,K)Fe2As2. Two large disk-shaped samples were fabricated using common industrial processing techniques under the best conditions deduced from data- and researcher-driven methods. After magnetizing the samples, they could retain a magnetic field of 2.83 T as a quasi-permanent magnet, around 2.7 times the previous record, with decay rates less than −0.1 ppm/h, crucial for MRI scanners. The two approaches produced divergent microstructures, opening the door to redefining what makes for a superior superconducting material.

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通过数据和研究人员驱动的工艺设计，利用铁基超导体制造超强永磁体

铁基高温（高tc）超导体由于其独特的拓扑结构和超导特性，在下一代超强准永磁体材料中具有良好的应用潜力。然而，它们的非常规高tc超导性与各向异性配对和短相干长度矛盾地联系在一起，在多晶材料中抑制晶界处的超电流传输带来了挑战。在本研究中，我们通过定制软件集成研究人员和数据驱动方法的工艺设计，利用机器学习来操纵复杂的多晶微结构。我们的方法产生了块体Ba0.6K0.4Fe2As2永磁体，其磁场比先前报道的强2.7倍。此外，我们还展示了实用的1.5 T永磁体的磁场稳定性超过0.1 ppm/h，这是医学磁共振成像的一个重要方面。纳米结构分析揭示了数据驱动和研究驱动过程的对比结果，表明高密度缺陷和双极化晶界间距分布是磁体卓越强度和稳定性的主要贡献者。铁基超导体在量子计算和超强磁体等方面很有前景。然而，提高它们的超导性能是具有挑战性的。本研究旨在利用贝叶斯优化技术改善k掺杂Ba122超导体的这些性能。研究人员在不同条件下制作了样品，并测量了它们的超导性能，以改进这一过程。利用数据驱动和研究人员驱动的方法找到的最佳处理条件，制作了两个大的圆盘形样品。在低温下测试了这些样品的超导特性，以及它们作为磁铁的能力。结果显示出显著的改进，证明了优化过程的有效性，并产生了具有前所未有强度的铁基超导磁体。该研究得出结论，机器学习，特别是贝叶斯优化，可以显著推进高性能超导材料的开发。这可能会导致更高效、更强大的超导磁体用于各种用途。这份摘要最初是用人工智能起草的，然后由作者进行了修改和事实核查。世界上最强的铁基超导磁体已经制造出来。采用贝叶斯优化的机器学习方法改进了掺钾砷化铁钡（Ba，K）Fe2As2的超导性能。两个大的圆盘状样品是在从数据和研究人员驱动的方法推导出的最佳条件下，使用常见的工业加工技术制造的。将样品磁化后，它们可以保持2.83 T的准永磁体磁场，大约是之前记录的2.7倍，衰变率低于- 0.1 ppm/h，这对MRI扫描仪至关重要。这两种方法产生了不同的微观结构，打开了重新定义优越超导材料的大门。

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来源期刊

Npg Asia Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

15.40

自引率

1.00%

发文量

审稿时长

2 months

期刊介绍： NPG Asia Materials is an open access, international journal that publishes peer-reviewed review and primary research articles in the field of materials sciences. The journal has a global outlook and reach, with a base in the Asia-Pacific region to reflect the significant and growing output of materials research from this area. The target audience for NPG Asia Materials is scientists and researchers involved in materials research, covering a wide range of disciplines including physical and chemical sciences, biotechnology, and nanotechnology. The journal particularly welcomes high-quality articles from rapidly advancing areas that bridge the gap between materials science and engineering, as well as the classical disciplines of physics, chemistry, and biology. NPG Asia Materials is abstracted/indexed in Journal Citation Reports/Science Edition Web of Knowledge, Google Scholar, Chemical Abstract Services, Scopus, Ulrichsweb (ProQuest), and Scirus.