Co9Zn9Mn2手性磁体晶体生长与磁学性质研究

doi:10.12677/meng.2026.132008

期刊菜单

Co₉Zn₉Mn₂手性磁体晶体生长与磁学性质研究
Study on Crystal Growth and Magnetic Properties of Co₉Zn₉Mn₂ Chiral Magnets

DOI: 10.12677/meng.2026.132008, PDF,
作者: 赵琦, 唐浩博：北京工业大学材料科学与工程学院，北京
关键词: 晶体生长；自助熔剂法；手性磁体；拓扑磁性粒子；洛伦兹电镜；Crystal Growth； Self-Flux Method； Chiral Magnets； Topological Magnetic Particles； Lorentz Electron Microscopy

摘要: 手性磁体Co-Zn-Mn体系因其高居里温度为拓扑磁性粒子的室温应用带来了希望。目前Co-Zn-Mn体系研究中的材料主要依赖助熔剂方法生长制备，获得的样品尺寸相对较小。实现较大尺寸样品的制备对Co-Zn-Mn体系室温拓扑磁性的系统性研究和技术应用有重要意义。本研究以Co₉Zn₉Mn₂成分为研究对象，通过改善自助熔剂法实现了5 g规格Co₉Zn₉Mn₂晶体的生长，并系统研究了其磁学性质。

Abstract: The chiral Co-Zn-Mn alloy system has emerged as a promising candidate for room-temperature topological magnetic particles, owing to its elevated Curie temperatures. Samples currently used in research on the Co-Zn-Mn system are primarily grown and prepared using the flux method, resulting in samples of relatively small size. The preparation of relatively large-sized samples is crucial for systematic research and technological applications of room-temperature topological magnetism in the Co-Zn-Mn system. This study focuses on the composition of Co₉Zn₉Mn₂ and achieves the growth of 5-gram scale Co₉Zn₉Mn₂ crystals using a refined self-flux method and systematically investigated their magnetic properties.

文章引用：赵琦, 唐浩博. Co₉Zn₉Mn₂手性磁体晶体生长与磁学性质研究[J]. 冶金工程, 2026, 13(2): 63-70. https://doi.org/10.12677/meng.2026.132008

参考文献

[1]	Nayak, A.K., Kumar, V., Ma, T., Werner, P., Pippel, E., Sahoo, R., et al. (2017) Magnetic Antiskyrmions above Room Temperature in Tetragonal Heusler Materials. Nature, 548, 561-566. [Google Scholar] [CrossRef] [PubMed]
[2]	Zheng, F., Kiselev, N.S., Yang, L., Kuchkin, V.M., Rybakov, F.N., Blügel, S., et al. (2022) Skyrmion-Antiskyrmion Pair Creation and Annihilation in a Cubic Chiral Magnet. Nature Physics, 18, 863-868. [Google Scholar] [CrossRef]
[3]	Tang, J., Wu, Y., Wang, W., Kong, L., Lv, B., Wei, W., et al. (2021) Magnetic Skyrmion Bundles and Their Current-Driven Dynamics. Nature Nanotechnology, 16, 1086-1091. [Google Scholar] [CrossRef] [PubMed]
[4]	Foster, D., Kind, C., Ackerman, P.J., Tai, J.B., Dennis, M.R. and Smalyukh, I.I. (2019) Two-Dimensional Skyrmion Bags in Liquid Crystals and Ferromagnets. Nature Physics, 15, 655-659. [Google Scholar] [CrossRef]
[5]	Rybakov, F.N. and Kiselev, N.S. (2019) Chiral Magnetic Skyrmions with Arbitrary Topological Charge. Physical Review B, 99, Article 064437. [Google Scholar] [CrossRef]
[6]	Zheng, F., Rybakov, F.N., Kiselev, N.S., Song, D., Kovács, A., Du, H., et al. (2021) Magnetic Skyrmion Braids. Nature Communications, 12, Article No. 5316. [Google Scholar] [CrossRef] [PubMed]
[7]	Kent, N., Reynolds, N., Raftrey, D., Campbell, I.T.G., Virasawmy, S., Dhuey, S., et al. (2021) Creation and Observation of Hopfions in Magnetic Multilayer Systems. Nature Communications, 12, Article No. 1562. [Google Scholar] [CrossRef] [PubMed]
[8]	Fert, A., Cros, V. and Sampaio, J. (2013) Skyrmions on the Track. Nature Nanotechnology, 8, 152-156. [Google Scholar] [CrossRef] [PubMed]
[9]	Zhang, X., Zhou, Y., Ezawa, M., Zhao, G.P. and Zhao, W. (2015) Magnetic Skyrmion Transistor: Skyrmion Motion in a Voltage-Gated Nanotrack. Scientific Reports, 5, Article No. 11369. [Google Scholar] [CrossRef] [PubMed]
[10]	Kang, W., Huang, Y., Zhang, X., Zhou, Y. and Zhao, W. (2016) Skyrmion-Electronics: An Overview and Outlook. Proceedings of the IEEE, 104, 2040-2061. [Google Scholar] [CrossRef]
[11]	Yu, X.Z., Kanazawa, N., Onose, Y., Kimoto, K., Zhang, W.Z., Ishiwata, S., et al. (2011) Near Room-Temperature Formation of a Skyrmion Crystal in Thin-Films of the Helimagnet Fege. Nature Materials, 10, 106-109. [Google Scholar] [CrossRef] [PubMed]
[12]	Seki, S., Yu, X.Z., Ishiwata, S. and Tokura, Y. (2012) Observation of Skyrmions in a Multiferroic Material. Science, 336, 198-201. [Google Scholar] [CrossRef] [PubMed]
[13]	Kézsmárki, I., Bordács, S., Milde, P., Neuber, E., Eng, L.M., White, J.S., et al. (2015) Néel-Type Skyrmion Lattice with Confined Orientation in the Polar Magnetic Semiconductor Gav4s8. Nature Materials, 14, 1116-1122. [Google Scholar] [CrossRef] [PubMed]
[14]	Tokunaga, Y., Yu, X.Z., White, J.S., Rønnow, H.M., Morikawa, D., Taguchi, Y., et al. (2015) A New Class of Chiral Materials Hosting Magnetic Skyrmions beyond Room Temperature. Nature Communications, 6, Article No. 7638. [Google Scholar] [CrossRef] [PubMed]
[15]	Bocarsly, J.D., Heikes, C., Brown, C.M., Wilson, S.D. and Seshadri, R. (2019) Deciphering Structural and Magnetic Disorder in the Chiral Skyrmion Host Materials. Co_�� Zn_�� Mn_�� (��+��+�� = 20). Physical Review Materials, 3, Article 014402. [Google Scholar] [CrossRef] [PubMed]

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