移动的阿布里科索夫涡旋晶格产生低于40纳米的磁振子。

IF 34.9 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nature nanotechnology Pub Date : 2025-10-16 DOI:10.1038/s41565-025-02024-w

Oleksandr V Dobrovolskiy,Qi Wang,Denis Yu Vodolazov,Roland Sachser,Michael Huth,Sebastian Knauer,Alexander I Buzdin

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引用次数: 0

摘要

磁振子是自旋波的准粒子，是发展基于波的计算和混合量子技术的有希望的候选者。然而，随着天线尺寸的缩小，微波激发产生短波长的磁振子变得越来越具有挑战性。在这里，我们展示了另一种方法，利用磁通量量子（即Abrikosov涡旋）在相邻的Nb-C超导体中以超过1 km s-1的速度运动，在Co-Fe带中产生磁振子。运动的涡旋晶格通过静态和动态杂散场作用于磁层。我们的实验展示了亚40nm波长的磁振子的单向激发及其与运动涡旋的相干相互作用。反过来，Nb-C维持其低电阻状态，因为磁振子的产生从超导体中去除了能量。这一发现使芯片上的高速电驱动磁振子产生成为可能，并验证了磁振子激发的另一种方法。我们的方法可以适用于其他波激发，如表面声波，用于集成到先进的电子和混合量子系统中。

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Moving Abrikosov vortex lattices generate sub-40-nm magnons.

Magnons, the quasi-particles of spin waves, are promising candidates for developing wave-based computing and hybrid quantum technologies. However, generating short-wavelength magnons through microwave excitation becomes increasingly challenging because the excitation efficiency decreases as the antenna size shrinks. Here we demonstrate an alternative approach and generate magnons in a Co-Fe strip using magnetic flux quanta, that is, Abrikosov vortices, moving in an adjacent Nb-C superconductor at velocities exceeding 1 km s-1. The moving vortex lattice acts on the magnetic layer via both static and dynamic stray fields. Our experiments showcase the unidirectional excitation of sub-40-nm wavelength magnons and their coherent interaction with the moving vortices. In turn, the Nb-C sustains its low-resistive state because the magnon creation removes energy from the superconductor. This discovery enables high-speed on-chip electrically driven magnon generation and validates an alternative means of magnon excitation. Our approach could be adapted to other wave excitations, such as surface acoustic waves, for integration into advanced electronic and hybrid quantum systems.

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来源期刊

Nature nanotechnology 工程技术-材料科学：综合

CiteScore

59.70

自引率

0.80%

发文量

196

审稿时长

4-8 weeks

期刊介绍： Nature Nanotechnology is a prestigious journal that publishes high-quality papers in various areas of nanoscience and nanotechnology. The journal focuses on the design, characterization, and production of structures, devices, and systems that manipulate and control materials at atomic, molecular, and macromolecular scales. It encompasses both bottom-up and top-down approaches, as well as their combinations. Furthermore, Nature Nanotechnology fosters the exchange of ideas among researchers from diverse disciplines such as chemistry, physics, material science, biomedical research, engineering, and more. It promotes collaboration at the forefront of this multidisciplinary field. The journal covers a wide range of topics, from fundamental research in physics, chemistry, and biology, including computational work and simulations, to the development of innovative devices and technologies for various industrial sectors such as information technology, medicine, manufacturing, high-performance materials, energy, and environmental technologies. It includes coverage of organic, inorganic, and hybrid materials.