由磁子自旋耗散驱动的磁化翻转
Magnetization switching driven by magnonic spin dissipation.
作者信息
Choi Won-Young, Ha Jae-Hyun, Jung Min-Seung, Kim Seong Been, Koo Hyun Cheol, Lee OukJae, Min Byoung-Chul, Jang Hyejin, Shahee Aga, Kim Ji-Wan, Kläui Mathias, Hong Jung-Il, Kim Kyoung-Whan, Han Dong-Soo
机构信息
Center for Spintronics, Korea Institute of Science and Technology (KIST), Seoul, Republic of Korea.
Department of Materials Science and Engineering, Seoul National University, Seoul, Republic of Korea.
出版信息
Nat Commun. 2025 Jul 1;16(1):5859. doi: 10.1038/s41467-025-61073-w.
Efficient control of magnetization in ferromagnets is crucial for high-performance spintronic devices. Magnons offer a promising route to achieve this objective with reduced Joule heating and minimized power consumption. While most research focuses on optimizing magnon transport with minimal dissipation, we present an unconventional approach that exploits magnon dissipation for magnetization control, rather than mitigating it. By combining a single ferromagnetic metal with an antiferromagnetic insulator that breaks symmetry in spin transport across the layers while preserving the symmetry in charge transport, we realize considerable spin-orbit torques comparable to those found in non-magnetic metals, enough for magnetization switching. Our systematic experiments and comprehensive analysis confirm that our findings are a result of magnonic spin dissipation, rather than external spin sources. These results provide insights into the experimentally challenging field of intrinsic spin currents in ferromagnets, and open up possibilities for developing energy-efficient devices based on magnon dissipation.
铁磁体中磁化的有效控制对于高性能自旋电子器件至关重要。磁振子为实现这一目标提供了一条有前景的途径,可减少焦耳热并将功耗降至最低。虽然大多数研究集中在以最小的耗散优化磁振子输运,但我们提出了一种非常规方法,即利用磁振子耗散来控制磁化,而不是减轻它。通过将单一铁磁金属与反铁磁绝缘体相结合,该绝缘体在跨层自旋输运中打破对称性,同时在电荷输运中保持对称性,我们实现了与非磁性金属中相当的可观的自旋轨道转矩,足以实现磁化翻转。我们的系统实验和全面分析证实,我们的发现是磁振子自旋耗散的结果,而不是外部自旋源。这些结果为铁磁体中固有自旋电流这一实验上具有挑战性的领域提供了见解,并为开发基于磁振子耗散的节能器件开辟了可能性。
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