<p>The development of new high-temperature ultrasmall-size skyrmion materials holds immense significance for the promising applications of topological spintronic devices. In this study, we demonstrate that a high-pressure synthesis technique can significantly elevate the Curie temperature of Mn<sub>5</sub>Ge<sub>3.2</sub> crystals, from 294 to 350 K. It is possible that this enhancement arises from the combined effects of lattice contraction and increased Ge content, a conclusion supported by our Density Functional Theory calculations. Additionally, our real-space magnetic imaging reveals the stability of dipolar skyrmions with diameters of approximately 50 nm at room temperature and zero magnetic field. Our micromagnetic simulations closely replicate the diverse experimental topological magnetic textures observed. Furthermore, magnetotransport measurements indicate the potential for the electrical distinction between various topological magnetic textures in skyrmion-based devices. We also report deterministic manipulations on single dipolar skyrmions in confined nanostructures by using in-plane currents. The observation, electrical manipulation, and electrical detection of room-temperature ultrasmall topological magnetic textures underscore the potential of Mn<sub>5</sub>Ge<sub>3.2</sub> as a promising platform for spintronic device applications.</p>

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Enhanced Curie temperature and room-temperature 50-nm skyrmions achieved in hexagonal ferromagnet Mn5Ge3.2 synthesized via a high-pressure method

  • Yongsen Zhang,
  • Wei Liu,
  • Meng Shi,
  • Shuisen Zhang,
  • Sheng Qiu,
  • Yaodong Wu,
  • Jialiang Jiang,
  • Huanhuan Zhang,
  • Hui Han,
  • Kang Wang,
  • Dingfu Shao,
  • Zhenfa Zi,
  • Chao Ma,
  • Haifeng Du,
  • Mingliang Tian,
  • Shouguo Wang,
  • Jin Tang

摘要

The development of new high-temperature ultrasmall-size skyrmion materials holds immense significance for the promising applications of topological spintronic devices. In this study, we demonstrate that a high-pressure synthesis technique can significantly elevate the Curie temperature of Mn5Ge3.2 crystals, from 294 to 350 K. It is possible that this enhancement arises from the combined effects of lattice contraction and increased Ge content, a conclusion supported by our Density Functional Theory calculations. Additionally, our real-space magnetic imaging reveals the stability of dipolar skyrmions with diameters of approximately 50 nm at room temperature and zero magnetic field. Our micromagnetic simulations closely replicate the diverse experimental topological magnetic textures observed. Furthermore, magnetotransport measurements indicate the potential for the electrical distinction between various topological magnetic textures in skyrmion-based devices. We also report deterministic manipulations on single dipolar skyrmions in confined nanostructures by using in-plane currents. The observation, electrical manipulation, and electrical detection of room-temperature ultrasmall topological magnetic textures underscore the potential of Mn5Ge3.2 as a promising platform for spintronic device applications.